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41420 Publications

Spectral tomography for 3D mineral and chemical analysis

Da Assuncao Godinho, J. R.; Renno, A.; de Schryver, T.; Masschaele, B.

A new analytical tool for mineral analysis will be introduced: Laboratory-based Spectral 3D X-ray Computed Tomography (Sp-CT). Results from a spectral imaging detector, prototype installed inside a TESCAN CoreTOM micro-CT system, will be presented and discussed in the context of mineralogical and chemical analysis of geological materials. The technique will be demonstrated to allow:

a) 3D mineral classification from the transmitted energy spectrum characteristic of a mineral phase.
b) Quick bulk chemical quantification of heavy elements with K-edge > 20 keV at high concentrations that are difficult to analyse by other methods.
c) Reducing common CT artefacts such as scattering and beam hardening, as well as improved contrast by selectively choose the most convenient energy range.
The advantages of Sp-CT will open new possibilities in geometallurgy and minerals processing research to move from the predominant 2D based image characterization towards more representative 3D characterization. These are fundamental steps to enable automated and routine 3D characterization that ultimately has the potential to provide faster and lower cost analysis to, for example, the mining industry, as well as more comprehensive rock characterization technique for Earth sciences research.

Keywords: XRCT; spectral XRCT

  • Poster
    PRORA - 10. Fachtagung Prozessnahe Röntgenanalytik, 28.-29.11.2019, Berlin, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30581
Publ.-Id: 30581


Applications in the Resource Industry - Between Handheld Instruments and 4D Methods

Renno, A.; Da Assuncao Godinho, J. R.; Gutzmer, J.; Kelly, N.; Reuter, M.; Seidel, P.; Sittner, J.; Winardhi, C. W.

An exemplary overview of the use of X-ray-based analytical methods in the resource industry, underpinned by examples, gives a very heterogeneous picture. The use of these methods is considered in the exploration, mining, mechanical processing and metallurgical/chemical processing of primary and secondary mineral and metallic raw materials.
Although X-ray diffraction, fluorescence, absorption and luminescence as well as various tomographic methods cover a very broad spectrum of methods, in many cases their use is apparently rather arbitrary, regardless of the respective matrix, technology and location.
For example for offline characterisation of raw materials and intermediates, established and reliable methods as well as pure estimation methods are used. In inline analytics, ad-hoc analytical instruments are used in addition to metrologically well-proven measuring systems that are well integrated into the respective technological processes. The enforcement of state standards with regard to environmental protection and resource use leads to a significant increase in the use of analytical technology and increased requirements for the certification of procedures.
A conspicuous feature is the constantly growing use of mobile "handheld devices", which are often used at decisive points to control the flow of materials. Very often, it can be observed that these devices, which in principle are very powerful, work under their respective capabilities or lead to significantly wrong results due to insufficiently thought-out and implemented measuring methods.
Almost all inline analytical methods used for sorting or process monitoring have the characteristic that they only lead to binary decisions. A comprehensive characterization of the material flow, which would lead both to flexible adaptation of the technologies used subsequently and to a significantly more differentiated splitting of the material flow, is a consequence of the ever more complex properties of the primary and secondary raw materials. This is the result of the change to economic forms with significantly stronger elements of a circular economy.
On the basis of current research at the HIF, it is presented how such a multi-effective measuring system could be designed. Furthermore, the advantages of the use of 3D methods in the characterization of primary and secondary raw materials as well as in the description of technological processes will be demonstrated. Both spectral XRCT (X-Ray Computed Tomography) and dynamic time-resolved XRCT methods are used.

Keywords: Resource Industry; Process Analysis; X-Ray Methods

  • Invited lecture (Conferences)
    PRORA - 10. Fachtagung Prozessnahe Röntgenanalytik, 28.-29.11.2019, Berlin, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30580
Publ.-Id: 30580


Halogen analysis of sulphide minerals at the ultratrace level – first applications of the Dresden Super-SIMS

Renno, A.; Rugel, G.; Wiedenbeck, M.; Ziegenrücker, R.

The integration of an ion source having very high spatial resolution with a tandem accelerator is a long-standing concept for improving analytical selectivity and sensitivity by orders of magnitude [1]. Translating this design concept into reality has its challenges [e.g. 2,3], meaning this approach has seldom been employed for mineralogical and geochemical research [e.g. 4].
Supporting a strong focus on natural, metallic and mineral resources, the Helmholtz Institute Freiberg for Resource Technology installed a so-called Super-SIMS at the Ion Beam Center at HZDR in Dresden-Rossendorf; this highly novel tool is devoted to the characterization of minerals and ores. The secondary ion beam from a CAMECA IMS 7f-auto is injected into the 6MV Dresden Accelerator Mass Spectrometry [5] facility, which effectively eliminates all molecular species from the ion beam.
We will present the current status of this initiative and will report our first results from halogen determinations (F, Cl, Br, I) in both sphalerite and galena. These data demonstrate a systematic and significant change in the counting rates of all halogens in mineralogically distinct areas of both minerals. Furthermore, we will describe our concepts for the quantification of these data at ultratrace levels.

[1] Matteson (2008) Mass Spec Rev 27, 470-484. [2] Ender et al. (1997) NIMB 123, 575-578. [3] Fahey et al. (2016) Anal Chem 88, 7145-7153. [4] Sie et al. (2000) NIMB 172, 228-234. [5] Rugel et al. (2016) NIMB 370, 94-100.

Keywords: SIMS; Super-SIMS; Halogen; Sphalerite; Galena

Related publications

  • Lecture (Conference)
    GEOMÜNSTER 2019, 22.-25.09.2019, Münster, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30579
Publ.-Id: 30579


Halogen analysis at the ultratrace level – first applications of the Dresden Super-SIMS

Renno, A.; Akhmadaliev, S.; Belokonov, G.; Böttger, R.; Borany, J.; Kaever, P.; Meyer, M.; Noga, P.; Rugel, G.; Tiessen, C. J.; Wagner, N.; Wiedenbeck, M.; Wu, H.; Ziegenrücker, R.

The integration of an ion source having very high spatial resolution with a tandem accelerator is a long-standing concept for improving analytical selectivity and sensitivity by orders of magnitude [1]. Translating this design concept into reality has its challenges [e.g. 2,3], meaning this approach has seldom be used in the framework of geochemical research [e.g. 4].
Supporting a strong focus on natural, metallic and mineral resources, the Helmholtz Institute Freiberg for Resource Technology installed a so-called Super-SIMS at the Ion Beam Center at HZDR; this highly novel tool is devoted to the characterization of minerals and ores. The secondary ion beam from a CAMECA IMS 7f-auto is injected into the 6MV Dresden Accelerator Mass Spectrometry [5] facility, which quantitatively eliminates effectively all molecular species from the ion beam.
We will present the current status of this initiative and will report on the performance parameters of the Dresden Super-SIMS as well as first results from halogen determinations in sphalerite and galena. Furthermore, we will describe our concepts for the quantification of these data at the ultratrace level.
[1] Matteson (2008) Mass Spec Rev 27, 470-484. [2] Ender et al. (1997) NIMB 123 575-578. [3] Fahey et al. (2016) Anal Chem 88, 7145-7153. [4] Sie et al. (2000) NIMB 172, 228-234. [5] Rugel et al. (2016) NIMB 370 94-100.

Keywords: SIMS. Super-SIMS; Sphalerite; Halogen

Related publications

  • Lecture (Conference)
    GOLDSCHMIDT 2019, 18.-23.08.2019, Barcelona, Spanien

Permalink: https://www.hzdr.de/publications/Publ-30578
Publ.-Id: 30578


Single-Shot Multi-keV X-Ray Absorption Spectroscopy Using an Ultrashort Laser-Wakefield Accelerator Source

Kettle, B.; Gerstmayr, E.; Streeter, M. J. V.; Albert, F.; Baggott, R. A.; Bourgeois, N.; Cole, J. M.; Dann, S.; Falk, K.; Gallardo González, I.; Hussein, A. E.; Lemos, N.; Lopes, N. C.; Lundh, O.; Ma, Y.; Rose, S. J.; Spindloe, C.; Symes, D. R.; Smid, M.; Thomas, A. G. R.; Watt, R.; Mangles, S. P. D.

Single-shot absorption measurements have been performed using the multi-keV x rays generated by alaser-wakefield accelerator. A 200 TW laser was used to drive a laser-wakefield accelerator in a modewhich produced broadband electron beams with a maximum energy above 1 GeVand a broad divergence of ≈15mrad FWHM. Betatron oscillations of these electrons generated1.2 0.2×106photons=eV in the5 keV region, with a signal-to-noise ratio of approximately 300∶1. This was sufficient to allow high-resolution x-ray absorption near-edge structure measurements at theKedge of a titanium sample in a singleshot. We demonstrate that this source is capable of single-shot, simultaneous measurements of both theelectron and ion distributions in matter heated to eV temperatures by comparison with density functionaltheory simulations. The unique combination of a high-flux, large bandwidth, few femtosecond durationx-ray pulse synchronized to a high-power laser will enable key advances in the study of ultrafast energeticprocesses such as electron-ion equilibration.

Permalink: https://www.hzdr.de/publications/Publ-30577
Publ.-Id: 30577


Laser-wakefield accelerators for high-resolution X-ray imaging of complex microstructures

Hussein, A. E.; Senabulya, N.; Ma, Y.; Streeter, M. J. V.; Kettle, B.; Dann, S. J. D.; Albert, F.; Bourgeois, N.; Cipiccia, S.; Finlay, O.; Gerstmayr, E.; Gallardo Gonzales, I.; Higginbotham, A.; Jaroszynski, D. A.; Falk, K.; Krushelnick, K.; Lemos, N.; Lopes, N. C.; Lumsdon, C.; Lundh, O.; Mangles, S. P. D.; Najmudin, Z.; Rajeev, P. P.; Schlepütz, C. M.; Shahzad, M.; Smid, M.; Spesyvtsev, R.; Symes, D. R.; Vieux, G.; Willingale, L.; Wood, J. C.; Shahani, A. J.; Thomas, A. G. R.

Laser-wakefield accelerators (LWFAs) are high acceleration-gradient plasma-based particle accelerators capable of producing ultra-relativistic electron beams. Within the strong focusing fields of the wakefield, accelerated electrons undergo betatron oscillations, emitting a bright pulse of X-rays with a micrometer-scale source size that may be used for imaging applications. Non-destructive X-ray phase contrast imaging and tomography of heterogeneous materials can provide insight into their processing, structure, and performance. To demonstrate the imaging capability of X-rays from an LWFA we have examined an irregular eutectic in the aluminum-silicon (Al-Si) system. The lamellar spacing of the Al-Si eutectic microstructure is on the order of a few micrometers, thus requiring high spatial resolution. We present comparisons between the sharpness and spatial resolution in phase contrast images of this eutectic alloy obtained via X-ray phase contrast imaging at the Swiss Light Source (SLS) synchrotron and X-ray projection microscopy via an LWFA source. An upper bound on the resolving power of 2.7 ± 0.3 μm of the LWFA source in this experiment was measured. These results indicate that betatron X-rays from laser wakefield acceleration can provide an alternative to conventional synchrotron sources for high resolution imaging of eutectics and, more broadly, complex microstructures.

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Permalink: https://www.hzdr.de/publications/Publ-30576
Publ.-Id: 30576


Renewable Methanol Synthesis

Roode-Gutzmer, Q. I.; Kaiser, D.; Bertau, M.

Renewable methanol production is an emerging technology that bridges the gap in the shift from fossil fuel to renewable energy. Two thirds of the global emission of CO₂ stems from humanity’s increasing energy need from fossil fuels. Renewable energy, mainly from solar and wind energy, suffers from supply intermittency, which current grid infrastructures cannot accommodate. Excess renewable energy can be harnessed to power the electrolysis of water to produce hydrogen, which can be used in the catalytic hydrogenation of waste CO₂ to produce renewable methanol. This review considers methanol production in the current context, regionally for Europe, which is dominated by Germany, and globally by China. Appropriate carbon-based feedstock for renewable methanol production is considered, as well as state-of-the-art renewable hydrogen production technologies. The economics of renewable methanol production necessitates the consideration of regionally relevant methanol derivatives. The thermodynamics, kinetics, catalytic reaction mechanism, operating conditions and reactor design are reviewed in the context of renewable methanol production to reveal the most up to date understanding.

Keywords: Catalysis; Energy storage; Hydrogenation of CO₂; Renewable methanol; Waste CO₂

Permalink: https://www.hzdr.de/publications/Publ-30575
Publ.-Id: 30575


Convection and electrovortex flow in liquid metal batteries

Cheng, J. S.; Mohammed, I.; Horstmann, G. M.; Kelley, D. H.

We study thermal convection and electrovortex flow (EVF) in series of liquid gallium laboratory experiments. These two forces notably interact in liquid metal batteries (LMBs), a promising technology suited for grid-scale energy storage: convection occurs due to the presence of internal heating while EVF is driven by diverging current densities. Though these forces have potential to both help and hinder the batteries’ operation, flow structures and scaling properties in this context remain largely unknown. To this end, we present a suite of velocity measurements which reveal the dominant flow modes and typical flow speeds over broad ranges of convective forcing, EVF forcing, and container shape. These data are compared to predictions from both the EVF and convection literature.

  • Lecture (Conference) (Online presentation)
    25th International Congress of Theoretical and Applied Mechanics (25th ICTAM), 23.-28.08.2020, Milano, Italien

Permalink: https://www.hzdr.de/publications/Publ-30574
Publ.-Id: 30574


Damped interfacial wave mechanics in orbitally shaken cylinders

Horstmann, G. M.; Anders, S.; Herreman, W.; Weier, T.

We present a new theoretical model describing damped gravity-capillary waves in orbitally shaken cylinders. Our model
can account for both free-surface and two-layer interfacial waves and is therefore versatilely applicable to two different devices: to
study interfacial wave instabilities in liquid metal batteries and to better predict mixing regimes in orbitally shaken bioreactors. We
complement a potential model with viscous damping rates to incorporate energy dissipation. This approach allows us to calculate
explicit formulas for the responding amplitudes and the phase shifts between wave and shaker, which are in good agreement with our
experiments. As an unexpected result, the model predicts the formation of novel spiral wave patterns under the influence of strong
damping. By employing a Background-Oriented Schlieren method we can experimentally verify their existence.

  • Lecture (Conference) (Online presentation)
    25th International Congress of Theoretical and Applied Mechanics (25th ICTAM), 23.-28.08.2020, Milano, Italien

Permalink: https://www.hzdr.de/publications/Publ-30573
Publ.-Id: 30573


The role of gas impurities on the optical properties of sputtered Ti(Al)N coatings

Bohovičová, J.; Meško, M.; Méndez, Á.; Julin, J. A.; Munnik, F.; Hübner, R.; Grenzer, J.; Čaplovič, Ľ.; Krause, M.

In this study, we investigated the role of impurities, such as H, C, and O on the optical properties of the Ti(Al)N coatings. For comparison, coatings were prepared by direct-current magnetron sputtering (DC-MS) and high-power impulse magnetron sputtering (HiPIMS) at the same average power. The elemental composition of the thin films was measured by elastic recoil detection analysis. Regardless of the deposition technique used, no significant difference in H and C concentrations were found. The analysis showed, that HiPIMS coatings contain less O impurities than the corresponding DC-MS films, despite the lower deposition rate. The reduced residual O content in HiPIMS coatings can be explained by the cleaning effect of the bombarding ions. Moreover, densification effects presumably suppress post-deposition oxidation. Given the reduced O content, HiPIMS films showed higher optical reflectance for the entire measured spectral range.

Related publications

  • Lecture (Conference)
    The 15th International Symposium on Sputtering and Plasma Processes, ISSP 2019, 11.-14.06.2019, Kanazawa, Japan
  • Poster
    The 15th International Symposium on Sputtering and Plasma Processes, ISSP 2019, 11.-14.06.2019, Kanazawa, Japan
  • Contribution to proceedings
    The 15th International Symposium on Sputtering and Plasma Processes, ISSP 2019, 11.-14.06.2019, Kanazawa, Japan

Permalink: https://www.hzdr.de/publications/Publ-30572
Publ.-Id: 30572


Interplay of solutal convection and electromagnetically driven flows in liquid metal battery electrodes

Weier, T.; Landgraf, S.; Nimtz, M.; Personnettaz, P.; Weber, N.; Sadoway, D.

Mass transfer in the positive electrode is one of the main factors determining the efficiency of liquid metal batteries. While solutal convection is quite intense during charge, discharge rates are limited by diffusion into a stable density stratification. The resulting concentration polarization can be substantially reduced if electrodynamically driven flows are employed to stir the liquid alloy. This leads to marked improvements in battery performance.

Keywords: solutal convection; electro-vortex flow; mass transfer; liquid metal battery

  • Lecture (Conference) (Online presentation)
    25th International Congress of Theoretical and Applied Mechanics, 22.-27.08.2021, Mailand, Italien

Permalink: https://www.hzdr.de/publications/Publ-30571
Publ.-Id: 30571


THEREDA – Thermodynamic Reference Database

Moog, H. C.; Scharge, T.; Bok, F.; Brendler, V.; Richter, A.; Morin, D.; Thoenen, T.; Altmaier, M.; Cevirim-Papaioannou, N.; Gaona, X.; Marquardt, C.; Freyer, D.; Pannach, M.; Sohr, J.

Part of the process to assess the safety of disposal sites for radioactive or chemical-toxic waste is the predictive modeling of the solubility of hazardous components in a complex aqueous solution. To ensure the reliability of thermodynamic equilibrium modeling as well as to facilitate the comparison of such calculations done by different institutions it is necessary to create a mutually accepted thermodynamic reference database.
To meet this demand in Germany several institutions joined efforts and created THEREDA. It contains a relational databank whose structure was designed in a way that promotes internal consistency of thermodynamic data. It serves as back end to a variety of supplementary programs which allow for adding, editing, and extracting subsets of data. Data considered cover the needs of Gibbs Energy Minimizers and Law-of-Mass-Action programs alike. Interaction parameters for an arbitrary number of mixed phases and p,T-functions of thermodynamic data may also be entered. At present, Pitzer- and SIT-parameters for the aqueous phase are considered.
To enhance public use THEREDA is accessible via internet.

Keywords: THEREDA; Thermodynamic Reference Database; Pitzer

  • Poster
    International Workshop on “How to integrate geochemistry at affordable costs into reactive transport for large-scale systems”, 05.-07.02.2020, Dresden, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30570
Publ.-Id: 30570


Ultrafast Mid-Infrared and Terahertz Phenomena in Graphene

Winnerl, S.

Graphene, the first atomically thin 2D material that was intensely investigated since its discovery in 2014, is a gapless semiconductor or semimetal with linear dispersion. Consequently, graphene absorbs light at all energies, in particular also at low photon energies in the THz frequency range. Here we show that pump-probe experiments at low photon energies can provide deep insights into the carrier dynamics. In particular, electron-phonon scattering can be disentangled from Coulomb scattering processes [1, 2]. Coulomb scattering in graphene is responsible for a number of unusual effects like strong Auger scattering under Landau quantization [3].
With respect to applications we present a graphene based detector with ultrafast response time of 40 ps. It operates in the very broad frequency range from visible to THz radiation [4].
[1] S. Winnerl, M. Orlita, P. Plochocka, P. Kossacki, M. Potemski, T. Winzer, E. Malic, A. Knorr, M. Sprinkle, C. Berger, W. A. de Heer, H. Schneider und M. Helm, Phys. Rev. Lett. 107, 237401 (2011).
[2] J. C. König-Otto, M. Mittendorff, T. Winzer, F. Kadi, E. Malic, A. Knorr, C. Berger, W. A. de Heer, A. Pashkin, H. Schneider, M. Helm und S. Winnerl, Phys. Rev. Lett. 117, 087401 (2016).
[3] M. Mittendorff, F. Wendler, E. Malic, A. Knorr, M. Orlita, M. Potemski, C. Berger, W. A. de Heer, H. Schneider, M. Helm und S. Winnerl, Nature Phys. 11, 75 (2015).
[4] M. Mittendorff, J. Kamann, J. Eroms, D. Weiss, C. Drexler, S. D. Ganichev, J. Kerbusch, A. Erbe, R. J. Suess, T. E. Murphy, S. Chatterjee, K. Kolata, J. Ohser, J. C. König-Otto, H. Schneider, M. Helm, S. Winnerl, Optics Express 23, 28728 (2015).

Keywords: graphene; terahertz; ultrafast

Related publications

  • Invited lecture (Conferences)
    Sino-German Bilateral Symposium on Low Dimensional Semiconductors and Opto-electronics Integration, 14.-17.11.2019, Changsha, China

Permalink: https://www.hzdr.de/publications/Publ-30568
Publ.-Id: 30568


Ge-based photoconductive emitters producing gapless broadband THz spectra

Singh, A.; Pashkin, O.; Winnerl, S.; Helm, M.; Schneider, H.

We present photoconductive emitters based on Ge featuring gapless broadband spectra up to 13 THz. Thus they can fill the gap in the 5 – 10 THz range and can be excited with fiber lasers.

Keywords: terahertz; broadband; photoconductive emitters

  • Lecture (Conference)
    CLEO/Europe-EQEC 2019, 23.-27.06.2019, Munich, Germany

Permalink: https://www.hzdr.de/publications/Publ-30567
Publ.-Id: 30567


Nonlinear THz resoponse of graphene plasmonic structures

Winnerl, S.; Jadidi, M. M.; Chin, M.; Seidl, A.; Schneider, H.; Helm, M.; Drew, H. D.; Murphey, T. E.; Mittendorff, M.

Ribbons and discs based on doped graphene feature strong tunable plasmonic resonances. We show that excitation with THz radiation results in strong changes of transmission, even at moderate pump fluences. The response is due to a broadening and redshift for the plasmonic absorption line as charge carriers are heated. The response time is determined by the cooling of carriers, which is of the order of 10 ps.

Keywords: graphene; plasmonics; nonlinear terahertz spectroscopy

Related publications

  • Invited lecture (Conferences)
    META 2019, the 10th International Conference on Metamaterials, Photonic Crystals and Plasmonics, 23.-26.07.2019, Lisbon, Portugal

Permalink: https://www.hzdr.de/publications/Publ-30566
Publ.-Id: 30566


Nonlinear THz spectroscopy in low-dimensional semiconductors using a free-electron laser

Winnerl, S.; Schmidt, J.; König-Otto, J.; Mittendorff, M.; Schneider, H.; Helm, M.

Sources for intense THz pulses allow one to investigate interesting nonlinear effects in various solid-state systems in a time-resolved manner. Here we discuss perturbative and non-perturbative nonlinear effects in graphene-based systems and GaAs/AlGaAs quantum wells, respectively, which are excited by intense, tunable, narrowband THz pulses from a free-electron laser (FEL).
For the graphene-based samples we have pursued two strategies to resonantly enhance the linear and nonlinear response. One way is to apply a magnetic field perpendicular to the graphene layer.
This splits the linear band structure into a set of non-equidistant Landau levels. Four-wave mixing experiments on the lowest Landau levels reveal a strong nonlinearity and a rapid dephasing of the microscopic polarization on sub-ps timescales [1]. The second path for resonant enhancement is the fabrication of ribbons and discs of doped graphene that feature a strong plasmonic response [2]. The nonlinearity corresponding to the plasmonic response is based on a red-shift and broadening of the absorption line caused by carrier heating.
While the previously discussed phenomena are perturbative nonlinear effects, FEL pulses are also well suited to generate non-perturbative effects such as the intraexcitonic Autler-Townes effect and double dressing of polaritons in microcavities [3, 4]. Here we present novel results on the dressing of subbands in a single GaAs/AlGaAs quantum well by THz photons. To this end, the transition between the second and third subband was resonantly pumped with the FEL. Broadband probing by THz time-domain spectroscopy using GaP crystals for optical rectification enabled us to observe the THz-dressing of the electronic states. Namely Autler-Townes splitting occurs at the transition between the first and second subband while the transition from the second to the third subband is split into a Mollow triplet.
We are grateful to our collaborators M. M. Jadidi, T. E. Murphy, A. Belyanin, and E. Malic.
REFERENCES
1. König-Otto, J. C., Wang, Y., Belyanin, A., Berger, C. de Heer, W. A., Orlita, M., Pashkin, A., Schneider, H., Helm, M., Winnerl, S. "Four-wave mixing in Landau-quantized graphene," Nano Lett., Vol. 17, 2184-2188, 2017.
2. Jadidi, M. M., Daniels, K. M., Myers-Ward, R. L., Gaskill, D. K., Konig-Otto, J. C., Winnerl, S., Sushkov, A. B., Drew, H. D., Murphy, T. E., Mittendorff, M. "Optical control of plasmonic hot carriers in graphene," ACS Photonics, Vol. 6, 302307, 2019.
3. Wagner, M., Schneider, H., Stehr, D., Winnerl, S., Andrews, A. M., Schartner, S., Strasser, G., Helm, M. "Observation of the intraexciton Autler-Townes effect in GaAs=AlGaAs semiconductor quantum wells," Phys. Rev. Lett., Vol. 105, 167401, 2010.
4. Pietka, B., Bobrovska, N., Stephan, D., Teich, M., Krol, M., Winnerl, S., Pashkin, A., Mirek, R., Lekenta, K., Morier-Genoud, F., Schneider, H., Deveaud, B., Helm, M., Matuszewski, M., Szczytko, J. "Doubly dressed bosons: exciton polaritons in a strong terahertz field," Phys. Rev. Lett., Vol. 119, 077403, 2017.

Keywords: Free-electron laser; terahertz; nonlinear spectroscopy; low-dimensional semiconductors

Related publications

  • Invited lecture (Conferences)
    Photonics & Electromagnetics Research Symposium (PIERS), 17.-20.06.2019, Rome, Italy

Permalink: https://www.hzdr.de/publications/Publ-30565
Publ.-Id: 30565


THz nonlinear optics in graphene ribbons

Jadidi, M. M.; Daniels, K. M.; Myers-Ward, R.; Gaskill, D. K.; König-Otto, J.; Winnerl, S.; Sushkov, A.; Drew, H. D.; Murphy, T. E.; Mittendorff, M.

Graphene plasmonics is an emerging field due the unique combination of spectral tunability, strong plasmonic resonance and low losses. Here we study the nonlinear optical properties of graphene bilayer ribbons, featuring a plasmonic resonance at 3.9 THz, in time resolved experiments. A redshift of the plasmonic resonance is observed upon excitation with picosecond THz pulses. The unconventional nonlinear effect is explained by the optical response of hot carriers. Already at fairly low fluences in the µJ/cm2 range strong changes in transmission in the 10 % range can be induced. This strong response, together with the fast recovery determined by the electron cooling time (∼10 ps), makes the system promising for optical switching applications.

Keywords: graphene; plasmonics; nonlinear optics

Related publications

  • Lecture (Conference)
    DPG-Frühjahrstagung, 31.03.-05.04.2019, Regensburg, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30564
Publ.-Id: 30564


High Power Lasers for Advanced Accelerator Development at the ELBE Center Dresden

Schramm, U.

Presentation of High Power Lasers Activities for
Advanced Accelerator Development
at the ELBE Center Dresden

Keywords: high power lasers

Related publications

  • Invited lecture (Conferences)
    Helmholtz Laser and Photonics Meeting 2019, 03.-04.12.2019, Hamburg, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30563
Publ.-Id: 30563


Emergence of nanoscale patterns under ion induced non-equilibrium conditions

Facsko, S.

Various self-organized nanoscale patterns emerge on surfaces which are irradiated by low- or medium-energy ion beams [1]. Depending on the irradiation conditions, hexagonally ordered dot or pit patterns, checkerboard patterns, as well as periodic ripple patterns are formed spontaneously due to the non-equilibrium conditions induced by continuous ion irradiation. In the collision cascade induced by an ion impact several defects, including interstitials, vacancies, ad-atoms and more complex defects are created. Below the recrystallization temperature, the surface is thus quickly amorphized by continuous ion irradiation and massive mass-transport takes place due to momentum-transfer from the ions to the near-surface atoms. Furthermore, ion sputtering is eroding the material non-homogeneously inducing a roughening instability.
On amorphous or amorphized surfaces, the formation of periodic patterns at high ion fluences results from an interplay of different roughening mechanisms, e.g. curvature dependent sputtering, ballistic mass redistribution, or altered surface stoichiometry on binary materials, and smoothing mechanisms, e.g. surface diffusion or viscous flow. Therefore, the patterns obey the symmetry given by the ion beam direction, i.e. hexagonal near order at normal incidence and two-fold symmetry with the ripple direction oriented perpendicular or parallel to the ion beam direction at off-normal incidence.
If the temperature during ion irradiation is above the recrystallization temperature of the material, ion induced defects are dynamically annealed and amorphization is prevented. The diffusion of ion-induced vacancies and ad-atoms on the crystalline surface is now additionally affected by the Ehrlich-Schwoebel barrier, like in molecular beam epitaxy. Vacancies and ad-atoms are trapped on terraces and can nucleate to form pits or terraces, respectively. Patterns formed in this regime exhibit the symmetry of the crystal structure of the irradiated surface and often have inverse pyramidal shapes with well-defined facets [2,3]. Therefore, this mechanism is called “reverse epitaxy”.
1.1. Ion induced patterns on Ge and GaAs
In Fig. 1 examples of ion irradiation induced pattern are shown for amorphized Ge surface (a, b) and for Ge (001) (c) and GaAs (001) (d) irradiated above their respective recrystallization temperatures of 250° and 200°C.
1.2. Modelling pattern formation by continuum equations
Pattern formation on ion irradiated surfaces can be modelled my atomistic simulation methods, such as molecular dynamics (MD) and Monte-Carlo (kMC), or by continuum equations. Due to the large area and high fluences, MD and MC cannot cover the large dynamic range, however, they can provide valuable insight into defect generation and ion induced mass transport. Continuum equations on the other hand are coarse grain approximations, which can cover much larger spatial and temporal regimes. Information from MD or MC can furthermore be used as input for predictive modelling of new materials and irradiation conditions.

Keywords: ion beams; ion-surface interaction; nanopattering

Related publications

  • Invited lecture (Conferences)
    23rd International Workshop on Inelastic Ion-Surface Collisions, 17.-22.11.2019, Matsue, Japan

Permalink: https://www.hzdr.de/publications/Publ-30562
Publ.-Id: 30562


Ion beam modification and ion beam analysis in current materials research

Facsko, S.; Heller, R.; Munnik, F.; Klingner, N.; Hlawacek, G.

Introduction to the IOne Beam Cneter and Current Research.

Keywords: Ion beam analysis; ion beam modification

Related publications

  • Lecture (Conference)
    NATO Advanced Training Course: “Spintronics Radar Detectors”, 14.-18.10.2019, Athens, Greece

Permalink: https://www.hzdr.de/publications/Publ-30561
Publ.-Id: 30561


Comparison of Si and Ge surface patterns produced by ion irradiation in the reverse epitaxy regime

Facsko, S.; Xin, O.; de Schultz, R.; Erb, D.

In addition to sputtering, ion irradiation is often also leading to restructuring of the surface and a plethora of surface patterns can appear. At irradiation temperatures high enough to dynamically anneal defects induced by the collision cascades the surface remains crystalline. Still, a high density of ion-induced surface vacancies and adatoms remains and their diffusion is affected by the Ehrlich-Schwoebel (ES) barrier, i.e. an additional diffusion barrier to cross terrace steps. These defects are therefore trapped on terraces, nucleate and form pits or mounds [1]. In this way three dimensional, faceted nanostructures are formed, reflecting the underlying crystal lattice. Due to the similarity to growth of three-dimensional structures in molecular beam epitaxy this mechanism is called reverse epitaxy.
We will present patterns on Si and Ge surface induced by low energy, normal incidence, high fluence ion irradiation at temperatures above the recrystallization temperature. Patterns with very different symmetry can result, depending on the surface orientation: pyramidal structures with four-fold symmetry on the (001) surface, with three-fold and six-fold symmetry on the (111) surface and elongated structures with two-fold symmetry on the (011) surface [2].
Although Si and Ge have the same diamond crystal lattice, the resulting patterns and facets are different: on Ge(001) predominantly (105) facets are formed, whereas (115) facets are found on Si(001). Similarly, on Si(111) the pattern exhibits a six-fold symmetry with (123) facets, whereas on Ge(111) the patterns are formed by (356) facets and exhibit a three-fold symmetry. The formation mechanism and possible effects leading to these differences on Ge and Si surfaces will be presented and discussed.

Keywords: ion beams; nanopatterning; ion-surface interaction

Related publications

  • Lecture (Conference)
    10th International Workshop on Nanoscale Pattern Formation at Surfaces (NanoPatterning 2019), 07.-10.07.2019, Surrey, England

Permalink: https://www.hzdr.de/publications/Publ-30560
Publ.-Id: 30560


The effects of intracranial stenosis on cerebral perfusion and cognitive performance

Hilal, S.; Mutsaerts, H. J. M. M.; Ferro, D. A.; Petr, J.; Kuijf, H.; Biessels, G. J.; Chen, C. P. L. H.

Objective: Intracranial stenosis (ICS) may contribute to cognitive dysfunction by decreased cerebral blood flow (CBF) which can be measured quantitatively by Arterial Spin Labelling (ASL). Interpretation of CBF measurements with ASL, however, becomes difficult in patients with vascular disease due to prolonged arterial transit time (ATT). Recently, spatial coefficient of variation (sCoV) of ASL signal has been proposed that approximates ATT and utilized as a proxy marker of vascular insufficiency. We investigated the association of ICS with both CBF and sCoV parameters and its eventual effects on cognition in a memory clinic population.

Methods: We included 381 patients (mean age=72.3±7.9years, women=53.7%) who underwent 3T MRI and detailed neuropsychological assessment. ICS was defined as ≥50% stenosis in any intracranial vessel on 3D Time of Flight MR Angiography. Gray matter sCoV and CBF were obtained from 2D EPI pseudo-continuous ASL images.

Results: ICS was present in 58 (15.2%) patients. Patients with ICS had higher gray matter sCoV and lower CBF. The association with sCoV remained statistically significant after correction for cardiovascular risk factors. Moreover, ICS was associated with worse performance on visuoconstruction which attenuated with higher sCoV. Mediation analysis showed that there was an indirect effect of ICS on visuoconstruction via sCoV.

Conclusion: These findings suggest that changes in vascular insufficiency as detected by sCoV plays an important role in cognitive impairment among individuals diagnosed with ICS. We also showed that sCoV partially mediates the link between ICS and cognition. Therefore, sCoV may provide valuable hemodynamic information in patients with vascular disease.

Permalink: https://www.hzdr.de/publications/Publ-30559
Publ.-Id: 30559


Interaction of low-energy ions with surfaces and 2D materials

Facsko, S.

The ion beam centre (IBC) of the Helmholtz-Zentrum Dresden-Rossendorf is a user facility primarily dedicated to research and application of ion beam techniques in materials research. The IBC comprises various ion beam facilities (accelerators, ion beam implanters, plasma-based ion beam equipment, focused / highly-charged ion facilities) which provide a wide energy range between 10 eV and 60 MeV. Besides these facilities, structural analysis (electron microscopy and spectroscopy, X-ray scattering techniques) and sample or device processing (under clean-room conditions) are part of the IBC to deliver a “complete” user service.
Special focus of the IBC is material research with low energy ions. Irradiations of surfaces with low energy ions can induce the formation of patterns with periodicities in the range of tens to hundreds of nanometers. At off-normal angle of incidence between 50° and 70° to the surface normal ripple patterns oriented perpendicular to the ion beam direction are observed. At normal incidence or for incidence angles smaller than 50° smoothing dominates on elemental materials, like Si and Ge. However, in contrast to irradiations at room temperature pattern formation is observed at normal ion incidence irradiations performed at temperatures above the recrystallization temperature of the material. Depending on the surface orientation checkerboard patterns with two-fold, three-fold, or six-fold symmetry reflecting the crystal structure of the irradiated surface are formed (Fig. 1).
Moreover, single impacts of low energy ions are used to create nanostructures and in thin membranes and for doping of 2D materials, like graphene and MoS2. In this case of highly charged ions the release of the potential leads to a local phase transformation of the material and subsequently to the formation of dots, pits or holes. Currently, a new facility for low energy ion nanoengineering is commissioned comprising a 100 keV accelerator for ion irradiations and MEIS, thin film deposition system, and different analytic tools for nanoscale analysis and characterization.

Keywords: ion beams; ion surface interaction; 2D materials

Related publications

  • Lecture (others)
    Physics Seminar, 26.05.2019, Uppsala, Schweden

Permalink: https://www.hzdr.de/publications/Publ-30558
Publ.-Id: 30558


Advancing laser plasma accelerators by means of femto-scale diagnostics

Schramm, U.

Invited talk on the role of femtoscale probing on laser plasma particle acceleration

Keywords: laser plasma accelerator

Related publications

  • Invited lecture (Conferences)
    Conference on High Intensity and Attosecond Laser Science CHILI, 09.-11.12.2019, Tel Aviv, Israel
  • Invited lecture (Conferences) (Online presentation)
    7th anual MT meeting, 15.-17.06.2021, Jülich, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30557
Publ.-Id: 30557


Joining of two different ceramic nanomaterials for bottom-up fabrication of heterojunction devices

Rajbhar, M.; Das, P.; Satpati, B.; Möller, W.; Facsko, S.; Böttger, R.; Ramgir, N.; Chatterjee, S.

Fabrication of device though bottom-up approach and using nanowires as building blocks has received significant attention as one can build flexible electronics which can handle stress better than thin film based device. However successful joining of the nanowires for fabrication of such device remains a challenge till date. While several well researched joining techniques are available for metal based nanowires, the same for ceramic nanowires is scarce at present. In this work we explore ion beam induced formation of heterojunction between two metal oxide nanowires, namely hydrogen titanate (H2Ti3O7) and cuprous oxide (Cu2O). The electron microscopy studies reveal detailed structural modifications at the joining sections. The ion beam modifications are explained using state-of-the-art TRI3DYN simulations, which details about migration of atoms, defects, sputtering, redeposition and atomic mixing between the two nanowires and emphasize that such junction formation is caused mainly due to atomic collisional effects.

Keywords: Ceramic nanomaterials; Metal oxides; Welding; Heterojunction; Ion-surface interaction; Nanowires

Related publications

Permalink: https://www.hzdr.de/publications/Publ-30556
Publ.-Id: 30556


How to develop a radiotracer for imaging of a molecular target in the brain

Deuther-Conrad, W.

How to develop a radiotracer for imaging of a molecular target in the brain: [18F]Fluspidine from layout to application in humans

  • Lecture (others)
    Institutskolloquium, 16.01.2020, Leipzig, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30555
Publ.-Id: 30555


Characterizing laser-plasma ion accelerators driving an intense neutron beam via nuclear signatures

Favalli, A.; Guler, N.; Henzlova, D.; Croft, S.; Falk, K.; Gautier, D. C.; Ianakiev, K. D.; Iliev, M.; Palaniyappan, S.; Roth, M.; Fernandez, J. C.; Swinhoe, M. T.

Compact, bright neutron sources are opening up several emerging applications including detection of nuclear materials for national security applications. At Los Alamos National Laboratory, we have used a short-pulse laser to accelerate deuterons in the relativistic transparency regime. these deuterons impinge on a beryllium converter to generate neutrons. During the initial experiments where these neutrons were used for active interrogation of uranium and plutonium, we observed β-delayed neutron production from decay of 9Li, formed by the high-energy deuteron bombardment of the beryllium converter. Analysis of the delayed neutrons provides novel evidence of the divergence of the highest energy portion of the deuterons (i.e., above 10 MeV/nucleon) from the laser axis, a documented feature of the breakout afterburner laser-plasma ion acceleration mechanism. these delayed neutrons form the basis of non-intrusive diagnostics for determining the features of deuteron acceleration as well as monitoring neutron production for the next generation of laser-driven neutron sources.

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Permalink: https://www.hzdr.de/publications/Publ-30554
Publ.-Id: 30554


DDR1 (discoidin domain receptor tyrosine kinase 1) drives glioblastoma therapy resistance by modulating autophagy

Vehlow, A.; Cordes, N.

Therapy resistance of tumor cells is a major obstacle for efficient anticancer treatment approaches and has been attributed to tumor heterogeneity as well as genetic and epigenetic changes. Accumulating evidence demonstrates that tumor cell adhesion to the extracellular matrix acts as an additional essential factor conferring tumor cell resistance to both radio- and chemotherapeutic intervention.
Our recent study demonstrates that DDR1 (discoidin domain receptor tyrosine kinase 1) elicits therapy resistance of glioblastoma multiforme (GBM) stem-like and bulk cells through its adhesion to extra-cellular matrix and the subsequent modulation of macroautophagy/autophagy. Mechanistically, DDR1 associates with a YWHA/14–3-3-BECN1-AKT1 multiprotein complex favoring pro-survival/anti-autophagic and resistance-mediating AKT-MTOR signaling. In turn, inhibition of DDR1 sensitizes glioblastoma cells to radio- and chemotherapy by inducing autophagy. Collectively, our study suggests that DDR1 may be a potential target for sensitizing glioblastoma cells to combination therapies through its efficient induction of autophagic cell death.

Keywords: Autophagy; discoidin domain receptor tyrosine kinase 1; glioblastoma; radiochemotherapy; therapy resistance

Permalink: https://www.hzdr.de/publications/Publ-30552
Publ.-Id: 30552


Impact of Cancer-Associated Fibroblast on the Radiation-Response of Solid Xenograft Tumors

Steer, A.; Cordes, N.; Jendrossek, V.; Klein, D.

Increasing evidence indicates that the heterogeneous tumor stroma supports therapy resistance at multiple levels. Fibroblasts, particularly cancer-associated fibroblasts (CAFs) are critical components of the tumor stroma. However, the impact of CAFs on the outcome of radiotherapy (RT) is poorly understood. Here, we investigated if and how fibroblasts/CAFs modulate the radiation response of malignant tumors by altering cancer cell radiosensitivity or radioresistance in vitro and in vivo. The influence of fibroblasts on cancer cell proliferation, cell death induction and long-term survival after RT was studied using different sets of fibroblasts and cancer cells in an indirect co-culture (2D) system to analyse potential paracrine interactions or a 3D model to study direct interactions. Paracrine signals from embryonic NIH-3T3 fibroblasts promoted MPR31.4 prostate and Py8119 breast cancer cell proliferation. Indirect co-culture with L929 skin fibroblasts induced higher levels of apoptosis in irradiated MPR31.4 cells, while they promoted proliferation of irradiated Py8119 cells. In addition, NIH-3T3 fibroblasts promoted long-term clonogenic survival of both tumor cell types upon irradiation in the 3D co-culture system when compared to non-irradiated controls. Also in vivo, co-implantation of cancer cells and fibroblasts resulted in different effects depending on the respective cell combinations used: co-implantation of MPR31.4 cells with NIH-3T3 fibroblasts or of Py8119 cells with L929 fibroblasts led to increased tumor growth and reduced radiation-induced tumor growth delay when compared to the respective tumors without co-implanted fibroblasts. Taken together, the impact of fibroblasts on cancer cell behavior and radiation sensitivity largely depended on the respective cell types used as they either exerted a pro-tumorigenic and radioresistance-promoting effect, an anti-tumorigenic effect, or no effect. We conclude that the plasticity of fibroblasts allows for such a broad spectrum of activities by the same fibroblast and that this plasticity is at least in part mediated by cancer cell-induced fibroblast activation toward CAFs.

Keywords: cancer-associated fibroblast; fibroblast; cancer therapy; radiation therapy; radiation resistance; tumor stoma; tumor microenvironment

Permalink: https://www.hzdr.de/publications/Publ-30549
Publ.-Id: 30549


Network-based analysis of prostate cancer cell lines reveals novel marker gene candidates associated with radioresistance and patient relapse

Seifert, M.; Peitzsch, C.; Gorodetska, I.; Börner, C.; Klink, B.; Dubrovska, A.

Radiation therapy is an important and effective treatment option for prostate cancer, but high-risk patients are prone to relapse due to radioresistance of cancer cells. Molecular mechanisms that contribute to radioresistance are not fully understood. Novel computational strategies are needed to identify radioresistance driver genes from hundreds of gene copy number alterations. We developed a network-based approach based on lasso regression in combination with network propagation for the analysis of prostate cancer cell lines with acquired radioresistance to identify clinically relevant marker genes associated with radioresistance in prostate cancer patients. We analyzed established radioresistant cell lines of the prostate cancer cell lines DU145 and LNCaP and compared their gene copy number and expression profiles to their radiosensitive parental cells. We found that radioresistant DU145 showed much more gene copy number alterations than LNCaP and their gene expression profiles were highly cell line specific. We learned a genome-wide prostate cancer-specific gene regulatory network and quantified impacts of differentially expressed genes with directly underlying copy number alterations on known radioresistance marker genes. This revealed several potential driver candidates involved in the regulation of cancer-relevant processes. Importantly, we found that ten driver candidates from DU145 (ADAMTS9, AKR1B10, CXXC5, FST, FOXL1, GRPR, ITGA2, SOX17, STARD4, VGF) and four from LNCaP (FHL5, LYPLAL1, PAK7, TDRD6) were able to distinguish irradiated prostate cancer patients into early and late relapse groups. Moreover, in-depth in vitro validations for VGF (Neurosecretory protein VGF) showed that siRNA-ediated gene silencing increased the radiosensitivity of DU145 and LNCaP cells. Our computational approach enabled to predict novel radioresistance driver gene candidates. Additional preclinical and clinical studies are required to further validate the role of VGF and other candidate genes as potential biomarkers for the prediction of radiotherapy responses and as potential targets for radiosensitization of prostate cancer.

Permalink: https://www.hzdr.de/publications/Publ-30548
Publ.-Id: 30548


Impact of prophylactic cranial irradiation on overall survival of patients with advanced non-small-cell lung cancer

Schmidt, J.; Appold, S.; Troost, E. G. C.

Hintergrund: In einer randomisierten Phase-III-Studie sollte untersucht werden, ob eine prophylaktische Ganzhirnbestrahlung bei kurativ-intendiert behandelten Patienten mit einem nicht-kleinzelligen Bronchialkarzinom (NSCLC) im Stadium III Einfluss auf das Auftreten von symptomatischen Hirnmetastasen hat.

Permalink: https://www.hzdr.de/publications/Publ-30547
Publ.-Id: 30547


Can Local Ablative Radiotherapy Revert Castration-resistant Prostate Cancer to an Earlier Stage of Disease

Lohaus, F.; Zöphel, K.; Löck, S.; Wirth, M.; Kotzerke, J.; Krause, M.; Baumann, M.; Troost, E. G. C.; Hölscher, T.

In prostate cancer, disease progression after primary treatment and subsequent androgen deprivation therapy is common. Intensification of systemic treatment is the standard of care. Recently, 68[16_TD$DIFF]Ga prostate-specific membrane antigen positron emission tomography (PSMA-PET) imaging was introduced to identify oligometastatic prostate cancer patients. In this retrospective, exploratory study, we report on the efficacy of PSMA-PET-guided local ablative radiotherapy (aRT) in 15 oligometastatic castrationresistant prostate cancer (CRPC) patients, selected from our prospective institutional database and treated between 2013 and 2016. After multidisciplinary discussion, aRT was delivered with two different schedules. Androgen deprivation therapy remained unchanged. Prostate-specific antigen (PSA) response and time to PSA progression were analysed. For comparison, individual time to PSA progression without aRT was estimated by individual PSA doubling time (PSADT). PSA response was observed in 11 patients (73%). Mean time to PSA progression or last follow-up was 17.9 mo, as opposed to 2.9 mo estimated from the PSADT without aRT (p <0.001). A relevant subset of CRPC patients had a PSA response with aRT to PET-positive lead metastases. A prospective trial is in preparation.
Patient summary: In selected patients with prostate-specific antigen (PSA) increase during androgen deprivation, metastases were detected with prostate-specific membrane antigen positron emission tomography imaging. Fifteen patients with three or fewer metastases were treated with high-dose radiotherapy. Subsequently, PSA values dropped in 11 patients and in six patients no PSA progression was detected for >12 mo.

Keywords: Castration-resistant prostate; cancer; Ablative radiotherapy; Stereotactic ablative body; radiotherapy; Oligometastatic prostate cancer; Prostate-specific membrane; antigen positron emission; tomography

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  • Secondary publication expected

Permalink: https://www.hzdr.de/publications/Publ-30545
Publ.-Id: 30545


Some unusual effects in magnetic fields

Zherlitsyn, S.

für diesen Vortrag hat keine inhaltliche Kurzfassung vorgelegen

  • Invited lecture (Conferences)
    Humboldt-Kolleg, International Conference „To grasp the whole world”, 04.-06.12.2019, Lissabon, Portugal

Permalink: https://www.hzdr.de/publications/Publ-30544
Publ.-Id: 30544


Independent validation of tumour volume, cancer stem cell markers and hypoxia-associated gene expressions for HNSCC after primary radiochemotherapy

Linge, A.; Schmidt, S.; Baumann, M.; Krenn, C.; Bandurska-Luque, A.; Platzek, I.; Neubeck, V. C.; Appold, S.; Nowak, A.; Gudziol, V.; Buchholz, F.; Baretton, B. B.; Lohaus, F.; Löck, S.; Krause, M.

Objective: To independently validate the impact of tumour volume, p16 status, cancer stem cell (CSC) marker expression and hypoxia-associated gene signatures as potential prognostic biomarkers for patients with locally advanced head and neck squamous cell carcinoma (HNSCC), who underwent primary radiotherapy or radiochemotherapy (RCTx). These markers have previously been reported in a study of the German Cancer Consortium Radiation Oncology Group (DKTK-ROG) (Linge et al., 2016).
Materials and methods: In this retrospective monocentric study, 92 patients with locally advanced HNSCC were included. Univariable and multivariable logistic regressions and Cox models presented in the study of the DKTK-ROG were validated using the area under the curve (AUC) and the concordance index (ci), respectively. The primary endpoint of this study was loco-regional tumour control (LRC) after primary RCTx.
Results: Although both cohorts significantly differed in the proportion of the tumour subsites, the parameters tumour volume, p16 status and N stage could be validated regarding LRC and overall survival (OS) using multivariable Cox regression (LRC ci: 0.59, OS ci: 0.63). These models were slightly improved by combination with the putative CSC marker CD44 (LRC ci: 0.61, OS ci: 0.69). The logistic regression model for 2-year LRC based on tumour volume, p16 status and CD44 protein was validated with an AUC of 0.64. The patient stratification based on hypoxia-associated gene signatures status was similar to the original study but without significant differences in LRC and OS.
Conclusions: In this validation study, the inclusion of the putative CSC marker CD44 slightly improved the prognostic performance of the baseline parameters tumour volume, p16 status and N stage. No improvement was observed when including expressions of the hypoxia-associated gene signatures. Prospective validation on a larger cohort is warranted to assess the clinical relevance of these markers.

Keywords: Biomarker; HNSCC; Cancer stem cells; HPV; Hypoxia; Primary radiochemotherapy

Permalink: https://www.hzdr.de/publications/Publ-30543
Publ.-Id: 30543


In-situ Investigations of Solid-Liquid Interfaces by means of RBS

Baghban Khojasteh Mohammadi, N.; Apelt, S.; Bergmann, U.; Facsko, S.; Heller, R.

Solid-liquid interfaces are of crucial significance since their presence in nature is ubiquitous. They play a fundamental role in diverse fields as biology, fluid physics, radiation physics, geological and environmental research, surface science and electro-chemistry. Binnig and Rohrer (Nobel Price 1986) considered the significance of the solid-liquid interface as:

"The solid-liquid interface is, in our opinion, the interface of the future." [1]

Investigating phenomena at the interface of a solid and an aqueous solution, where chemical reactions, oxidation, corrosion, adhesion, dissolution and ion exchange may take place, represents a challenging task. The techniques applied should not influence any of these processes, they should be able to access the interface (through the liquid or through the solid) and simultaneously deliver quantitative information on the interface properties.

A new versatile experimental setup for in-situ Rutherford backscattering spectrometry at solid-liquid interfaces enabling direct and quantitative measurements with highest sensitivity is presented [2]. An electro-chemical liquid cell with a three-electrode arrangement was mounted at the IBCs 2MV Van-de-Graaff accelerator. A thin Si3N4 window (thickness down to 150 nm) separates the vacuum of the detector chamber from the electrolyte in the cell.

In a first study, we investigated the attachment of Ba onto the Si3N4 surface as a function of contact time and pH value of the electrolyte solution (see Fig. 1). From these measurements, we can deduce the evolution of the double layer with sub-monolayer sensitivity in a direct and quantitative manner.

Despite focusing on a particular system as presented here, the setup allows to conduct a large variety of in-situ investigations at solid-liquid interfaces such as monitoring of electro-chemical reactions, segregation, adsorption, dissolution and corrosion processes.

Details of the setup, its capabilities and limitations are presented and the results of first measurements are discussed in detail.

[1] G. Binnig and H. Rohrer, Reviews of Modern Physics 71 (1999), 324.
[2] N. B. Khojasteh, S. Apelt, U. Bergmann, S. Facsko and R. Heller, Review of Scientific Instruments (2019), submitted.

Keywords: Ion beam analysis; Rutherford backscattering; RBS; elemental analysis; solid-liquid interface; electric double layer

Related publications

  • Lecture (Conference)
    24th International Conference on Ion Beam Analysis, 13.-18.10.2019, Antibes, Frankreich

Permalink: https://www.hzdr.de/publications/Publ-30542
Publ.-Id: 30542


Modern Ion Beam Techniques for Elemental Analysis of Surfaces and Interfaces at the nm Scale

Heller, R.

The general trend in technology and science to create, process and analyze small structures on the nm scale leads to new challenges in modern ion beam analysis (IBA). This is accompanied by higher demands on the lateral resolution as well as on high precision determination of elemental compositions on an atomic depth scale.

Thinner layer structures are closely related to an increased sensitivity on external impacts. Even the transport of a sample to the place of analysis under ambient conditions can lead to unwanted (chemical) modifications at the surface. Furthermore, in technological developments not only the state of a system after processing but the process itself may be of particular interest. “Online” IBA under process conditions is thus highly desired.

Classical IBA methods like RBS (Rutherford Backscattering Spectrometry), ERD (Elastic Recoil Detection Analysis), PIXE (Particle Induced X-Ray Emission) or PIGE (Particle Induced Gamma Emission), either applied as broad beam or as a micro probe, can therefore quickly reach their limits.

In the present contribution, we give an overview on recent and ongoing developments of new IBA techniques and approaches at the HZDR Ion Beam Center (IBC) addressing the above-mentioned difficulties. These developments include in particular

  • the implementation of IBA in a helium ion microscope enabling elemental mapping on the nm scale,
  • the unification of different IBA techniques in complex experimental chambers including in-situ capabilities,
  • a new setup for in-operando, online and quantitative analysis of solid-liquid interfaces with sub mono-layer sensitivity,
  • A new low-energy ion laboratory equipped with a Medium Energy Ion Scattering (MEIS) chamber for quantitative elemental depth profiling on the nm scale.

We will give an overview on these techniques and their capabilities. Since the IBC is an international user facility all presented techniques are available for external users experiments.

Keywords: Ion beam analysis; elemental composition; imaging; materials analysis; nano scale; backscattering

Related publications

  • Poster
    18th European Conference on Applications of Surface and Interface Analysis, 15.-20.09.2019, Dresden, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30541
Publ.-Id: 30541


Efficacy and safety of carbon-ion radiotherapy for locally recurrent rectal cancer: results of the J-CROS Study 1404 Rectum

Jentsch, C.; Troost, E. G. C.

Hintergrund In dieser retrospektiven Arbeit untersuchten die Autoren die Wirksamkeit und Sicherheit einer Kohlenstoffionentherapie lokal rezidivierter Rektumkarzinome.

Permalink: https://www.hzdr.de/publications/Publ-30540
Publ.-Id: 30540


Photocatalytic biocidal effect of copper doped TiO2 nanotube coated surfaces under laminar flow, illuminated with UVA light on Legionella pneumophila

Oder, M.; Koklič, T.; Umek, P.; Podlipec, R.; Štrancar, J.; Dobeic, M.

Legionella pneumophila can cause a potentially fatal form of humane pneumonia (Legionnaires’ disease), which is most problematic in immunocompromised and in elderly people. Legionella species is present at low concentrations in soil, natural and artificial aquatic systems and is therefore constantly entering man-made water systems. The environment temperature for it’s ideal growth range is between 32 and 42°C, thus hot water pipes represent ideal environment for spread of Legionella. The bacteria are dormant below 20°C and do not survive above 60°C. The primary method used to control the risk from Legionella is therefore water temperature control. There are several other effective treatments to prevent growth of Legionella in water systems, however current disinfection methods can be applied only intermittently thus allowing Legionella to grow in between treatments. Here we present an alternative disinfection method based on antibacterial coatings with Cu-TiO2 nanotubes deposited on preformed surfaces. In the experiment the microbiocidal efficiency of submicron coatings on polystyrene to the bacterium of the genus Legionella pneumophila with a potential use in a water supply system was tested. The treatment thus constantly prevents growth of Legionella pneumophila in presence of water at room temperature. Here we show that 24-hour illumination with low power UVA light source (15 W/m2 UVA illumination) of copper doped TiO2 nanotube coated surfaces is effective in preventing growth of Legionella pneumophila. Microbiocidal effects of Cu-TiO2 nanotube coatings were dependent on the flow of the medium and the intensity of UV-A light. It was determined that tested submicron coatings have microbiocidal effects specially in a non-flow or low-flow conditions, as in higher flow rates, probably to a greater possibility of Legionella pneumophila sedimentation on the coated polystyrene surfaces, meanwhile no significant differences among bacteria reduction was noted regarding to non or low flow of medium.

Related publications

Permalink: https://www.hzdr.de/publications/Publ-30539
Publ.-Id: 30539


Correlation between FMISO-PET based hypoxia in the primary tumour and in lymph node metastases in locally advanced HNSCC patients

Bandurska-Luque, A.; Löck, S.; Haase, R.; Richter, C.; Zöphel, K.; Perrin, R.; Appold, S.; Krause, M.; Steinbach, J.; Kotzerke, J.; Hofheinz, F.; Zips, D.; Baumann, M.; Troost, E. G. C.

Purpose: This secondary analysis of the prospective study on repeat [18F]fluoromisonidazole (FMISO)-PET in patients with locally advanced head and neck squamous cell carcinoma (HNSCC) assessed the correlation of hypoxia in the primary tumour and lymph node metastases (LN) prior to and during primary radiochemotherapy.
Methods: This analysis included forty-five LN-positive HNSCC patients having undergone FMISO-PET/CTs at baseline, and at week 1, 2 and 5 of radiochemotherapy. The quantitative FMISO-PET/CT parameters maximum standardised uptake value (SUVmax, corrected for partial volume effect) and peak tumour-to-background ratio (TBRpeak) were estimated in the primary tumour as well as in index and large LN, respectively. Statistical analysis was performed using the Spearman correlation coefficient q.
Results: In 15 patients with large LN (FDG-PET positive volume >5 ml), there was a significant correlation between the hypoxia measured in the primary tumour and the large LN at three out of four time-points using the TBRpeak (baseline: q= 0.57, p = 0.006; week 2: q= 0.64, p = 0.003 and week 5: q= 0.68, p = 0.001). For the entire cohort (N = 45) only assessed prior to the treatment, there was a statistically significant, though weak correlation between FMISO-SUVmax of the primary tumour and the index LN (q= 0.36, p = 0.015).
Conclusions: We observed a significant correlation between FMISO-based hypoxia in the primary tumour and large lymph node(s) in advanced stage HNSCC patients. However, since most patients only had relatively small hypoxic lymph node metastases, a comprehensive assessment of the primary tumour and lymph node hypoxia is essential.

Keywords: Hypoxia; FMISO; PET; Primary tumour; Lymph node metastases; Locally advanced HNSCC; Radiochemotherpy

Permalink: https://www.hzdr.de/publications/Publ-30537
Publ.-Id: 30537


Morphology Modification of Si Nanopillars under Ion Irradiation at Elevated Temperatures

Xu, X.; Heinig, K.-H.; Möller, W.; Engelmann, H.-J.; Klingner, N.; Gharbi, A.; Tiron, R.; Borany, J.; Hlawacek, G.

Ion beam irradiation of vertical nanopillar structures can be utilized to fabricate a vertical gate-all-around (GAA) single electron transistor (SET) device in a CMOS-compatible way. After irradiation of Si nanopillars (with a diameter of 35 nm and a height of 70 nm) by either 50 keV broad beam Si+ or 25 keV focused Ne+ beam from a helium ion microscope (HIM) at room temperature and a fluence of 2e16 ions/cm2, strong deformation of the nanopillars has been observed which hinders further device integration. This is attributed to ion beam induced amorphization of Si allowing plastic flow due to the ion hammering effect, which, in connection with surface capillary forces, dictates the final shape. However, plastic deformation can be suppressed under irradiation at elevated temperatures (investigated up to 672 K). Then, as confirmed by bright-field transmission electron microscopy, the substrate and the nanopillars remain crystalline and are continuously thinned radially with increasing fluence down to a diameter of 10 nm. This is attributed to enhanced forward sputtering through the sidewalls of the pillar, and found in reasonable quantitative agreement with the predictions from 3D ballistic computer simulation using the TRI3DYN program.
This work is supported by the European Union’s H-2020 research project ‘IONS4SET’ under Grant Agreement No. 688072.

Related publications

  • Poster
    AVS 66th International Symposium & Exhibition, 24.10.2019, Columbus, USA

Permalink: https://www.hzdr.de/publications/Publ-30536
Publ.-Id: 30536


Realization of wafer-scale nanogratings with sub-50 nm period through vacancy epitaxy

Huang, Q.; Jia, Q.; Feng, J.; Huang, H.; Yang, X.; Grenzer, J.; Huang, K.; Zhang, S.; Lin, J.; Zhou, H.; You, T.; Yu, W.; Facsko, S.; Jonnard, P.; Wu, M.; Giglia, A.; Zhang, Z.; Liu, Z.; Wang, Z.; Wang, X.; Ou, X.

Gratings, one of the most important energy dispersive devices, are the fundamental building blocks for the majority of optical and optoelectronic systems. The grating period is the key parameter that limits the dispersion and resolution of the system. With the rapid development of large X-ray science facilities, gratings with periodicities below 50 nm are in urgent need for the development of ultrahigh-resolution X-ray spectroscopy. However, the wafer-scale fabrication of nanogratings through conventional patterning methods is difficult. Herein, we report a maskless and high-throughput method to generate wafer-scale, multilayer gratings with period in the sub-50 nm range. They are fabricated by a vacancy epitaxy process and coated with X-ray multilayers, which demonstrate extremely large angular dispersion at approximately 90 eV and 270 eV. The developed new method has great potential to produce ultrahigh line density multilayer gratings that can pave the way to cutting edge high-resolution spectroscopy and other X-ray applications.

Keywords: GRATINGS; SCATTERING; ARRAYS

Permalink: https://www.hzdr.de/publications/Publ-30535
Publ.-Id: 30535


High resolution materials modification with low fluence Helium Ion Microscopy

Hlawacek, G.

Helium Ion Microscopy (HIM) is best known for its high resolution imaging capabilities of both
conductive as well as insulating samples. However, since the introduction of Ne as a source gas for the
gas field ion source (GFIS) an increasing number of nano-fabrication applications are realized. While
the use of Neon as an imaging gas results in a somewhat lower lateral resolution (1.8 nm for 25 keV Ne +
compared to 0.5 nm for 30 keV He + ) the user usually benefits from the much higher cross section for
nuclear stopping. The latter results in a larger number of sputtered atoms, vacancies, interstitials and
chemical bonds broken directly by small impact parameter collisions.
After a brief introduction of the technique I will present results obtained using direct write milling, low
fluence ion beam irradiation and ion beam based mixing. In all cases the electronic, optical or magnetic
properties of the target material will be altered at the nano-scale in a controlled way to achieve new
functionality. The examples comprise
∙ Irradiation of 2D materials including a discussion on the achievable resolution
∙ The fabrication of a lateral spin valve and other magnetic structures using low fluence focused ion
beam irradiation
∙ Irradiation of Si nanostructures at elevated temperatures to avoid amorphization
∙ Irradiation of SiC with very low fluencies
For many of the presented examples the critical length scale of the nanostructure is smaller or in the
range of collision cascade. This size regime can not easily be accessed with traditional broad beam based
ion irradiation and holds many promises but also challenges that need to be overcome to enable new
device concepts and new functional materials on the nano-scale. The use of in-situ instrumentation to
characterize and influence the irradiated material during the irradiation is a key element for the above
examples.
This work is supported by the European Union’s H-2020 research project ‘IONS4SET’ under Grant
Agreement No. 688072.

Keywords: HIM; modification

Related publications

  • Invited lecture (Conferences)
    1st Sino-German Symposium on "Defect Engineering in SiC Device Manufacturing - Atomistic Simulations, Characterization and Processing" DESiC 2019, 12.11.2019, Peking, China

Permalink: https://www.hzdr.de/publications/Publ-30534
Publ.-Id: 30534


Up to 70 THz bandwidth from an implanted Ge photoconductive antenna excited by a femtosecond Er:fibre laser

Singh, A.; Pashkin, O.; Winnerl, S.; Welsch, M.; Beckh, C.; Sulzer, P.; Leitenstorfer, A.; Helm, M.; Schneider, H.

Phase-stable electromagnetic pulses in the THz frequency range offer several unique capabilities in time-resolved spectroscopy. However, the diversity of their application is limited by the covered spectral bandwidth. In particular, the upper frequency limit of photoconductive emitters - the most widespread technique in THz spectroscopy – reaches only up to 7 THz in the regular transmission mode due to the absorption by infrared-active optical phonons. Here, we present ultra-broadband (extending up to 70 THz) THz emission from an Au implanted Ge emitter which is compatible with modelocked fibre lasers operating at 1.1 and 1.55 um wavelengths with pulse repetition rates of 10 and 20 MHz, respectively. This result opens a perspective for the development of compact THz photonic devices operating up to multi-THz frequencies which are compatible with Si CMOS technology.

Related publications

Permalink: https://www.hzdr.de/publications/Publ-30533
Publ.-Id: 30533


Focused ion beam materials modification with noble gas ions

Hlawacek, G.

I will present results obtained using Helium Ion Microscopy (HIM) [1] in various nanostructuring projects. The common goal of the research is to change the electronic or magnetic properties of the target material at the nano-scale in a controlled way to achieve new functionality. Where applicable this new functionality will be measured in-situ during the nanostructure fabrication process.
For all presented examples the critical length scale of the nanostructure is smaller or in the range of collision cascade.
This size regime can not easily be accessed with traditional broad beam based ion irradiation and holds many promises but also challenges that need to be overcome to enable new device concepts and new functional materials on the nano-scale.

Related publications

  • Invited lecture (Conferences)
    IISC23, 20.11.2019, Matsue, Japan

Permalink: https://www.hzdr.de/publications/Publ-30532
Publ.-Id: 30532


Nanostructure characterization with ions

Hlawacek, G.

Helium Ion Microscopy (HIM) is best known for its high resolution imaging capabilities of both conductive as well as insulating samples. Over the last decade several efforts have been made to also add high spatial resolution analytic capabilities to the instrument. In many cases the starting point for these efforts was given by existing high energy ion beam analysis techniques. In particular TOF-RBS, magnetic sector SIMS and TOF-SIMS have successfully been realized. In addition in-situ probing, and in-operando methods are used to evaluate directly the effect of ion beam irradiation on nanostructures.
New developments aim at the improving of magnetic sector SIMS and the implementation of scanning transmission ion microscopy.
This work is supported by European Union’s H-2020 research project ‘npSCOPE’ under Grant Agree-ment No. 720964 and the FNR STHIM project under grant number I7748, and by the German BMWi via Grant 03ET7016 and 03THW12F01.

Keywords: HIM; SIMS; STIM

Related publications

  • Invited lecture (Conferences)
    8th EU Korea Nanoworkshop, 25.11.2019, Brüssel, Belgien

Permalink: https://www.hzdr.de/publications/Publ-30531
Publ.-Id: 30531


Analytic approaches for Helium Ion Microscopy

Klingner, N.; Hlawacek, G.; Laura, W.; Heller, R.

Helium Ion Microscopy (HIM) has become a wide spread imaging and nanofabrication technology.
However, existing HIM users can currently not perform elemental analysis in an easy and cost efficient
way. We present results obtained using a light weight retrofitable Time of Flight Secondary Ion Mass
Spectrometer (TOF-SIMS). I will briefly give an overview on new developments in our TOF-SIMS setup
which allows to obtain information on the elemental composition of the sample. The lateral resolution
for the presented TOF-SIMS add-on has been measured to be 8 nm. While not a dedicated high
mass resolution instrument it allows to answer many scientific questions by combining the high lateral
resolution of the HIM with elemental information. The examples include but are not limited to battery
materials and corrosion protection of steel.

Keywords: HIM; SIMS; batteries

Related publications

  • Lecture (Conference)
    AVS, 24.10.2019, Columbus, USA

Permalink: https://www.hzdr.de/publications/Publ-30530
Publ.-Id: 30530


Tailoring magnetic nanostructures with a He-Ne ion microscope

Hlawacek, G.; Bali, R.; Lenz, K.; Samad, F.; Peter, D.

Tailoring magnetic nanostructures with a He-Ne ion microscope

Keywords: HIM; magnetism

Related publications

  • Lecture (Conference)
    Spins, Waves and Interactions 2019, 5.9.2019, Greifswald, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30529
Publ.-Id: 30529


Avoiding amorphization during ion beam irradiation and critical dimension reduction of nanostructures

Xu, X.; Hlawacek, G.; Engelmann, H.-J.; Bischoff, L.; Heinig, K.-H.; Borany, J.

Ion beam induced collateral damage is becoming an issue in FIB processing, as it limits the
application of ion beams for nanostructure fabrication. This is of special importance for the
application of focused ion beams for nanostructure fabrication.
Here, we present an approach to mitigate the ion beam induced damage inflicted on semi -
conductor nanostructures during ion beam irradiation. Nanopillars (with a diameter of
35 nm and a height of 70 nm) have been irradiated with both, a 50 keV Si + broad beam and
a 25 keV focused Ne + beam from a helium ion microscope (HIM). Upon irradiation of the
nanopillars at room temperature with a medium fluence (2x10 16 ions/cm2), strong plastic
deformation has been observed which hinders further device integration. The shape and
crystallinity has been studied by HIM and TEM. This differs from predictions made by
Monte-Carlo based simulations using the TRI3DYN. However, irradiation at elevated tem-
peratures with the same fluence not only preserves the shape of the nanopillars but allows
for controlled diameter reduction by as much as 50 % without significant change in pillar
height.
It is well known that above a critical temperature amorphization of silicon is prevented in-
dependent of the applied fluence. At high enough temperatures and for not too high flux
this prevents the ion beam hammering and viscous flow of the nanostructures. These two
effects are responsible for the shape change observed at low temperature. We find that ir-
radiation above 650 K preserves the crystalline nature of the pillars and prevents viscous
flow. In addition, a steady thinning process of the nanopillars to a diameter of 10 nm with-
out a significant change in height is observed for higher fluencies at elevated temperatures.
As the original pillar diameter is smaller than the size of the collision cascade, enhanced
forward sputtering through the sidewalls of the pillar is responsible for this pillar-thinning
effect. Results for various ion beam energies, fluencies, fluxes and temperatures will be
presented and compared to TRI3DYN simulations. Such a reliable and CMOS-compatible
process could serve as a potential down scaling technique for large-scale fabrication of
nanostructure based electronics and many other FIB based milling applications.

Keywords: HIM

Related publications

  • Lecture (Conference)
    EU-F-N 2019, 14.6.2019, Dresden, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30528
Publ.-Id: 30528


Analytic approaches for Helium Ion Microscopy

Hlawacek, G.; Klingner, N.; Veligura, V.; Xu, X.; Serralta Hurtado De Menezes, E.; Schmeink, A. H.; Borany, J.; Facsko, S.

Helium Ion Microscopy (HIM) utilizes a Gas Field Ion Source (GFIS) to create a Helium or Neon
ion beam with a diameter better than 0.5 nm and 1.8 nm, respectively. The method is well known
for its high resolution imaging and nano-fabrication capabilities which it is able to provide not only for
conducting but also insulating samples without the need for a conductive coating. However, the existing
GFIS based focused ion beam (FIB) tools suffer from the lack of a well integrated analytic method that
can enrich the highly detailed morphological images with material properties contrast. While HIM
technology is relatively young several efforts have been made to add such an analytic capability to
the technique. So far, ionoluminescence, secondary electron spectroscopy, backscattering spectrometry
(BS), and secondary ion mass spectrometry (SIMS) using a magnetic sector or time of flight (TOF)
setup have been demonstrated. In addition in-situ experiments can be performed that allow to directly
and in real time investigate the effect of the focused ion beam on the materials under various conditions.
I will present our efforts to perform in-situ experiments in the Helium Ion Microscope and enhance its
analytic capabilities. In the first part of my presentation I will give an overview of the in-situ characteri-
zation capabilities of the HZDR Orion NanoFab including in-situ heating and electrical characterization.
In the second part of the talk I will focus on different analytic approaches tested in the past. I will
briefly give an overview on ionoluminescence in the HIM and than present our newly developed TOF-BS
and TOF-SIMS setup which allow to obtain information on the composition of the sample. They both
utilize the same cost efficient and minimal invasive pulsing scheme for the primary ion beam. The lateral
resolution reached for TOF-BS is approximately 50 nm while for TOF-SIMS a value of 8 nm could be
reached. First images will be presented and the performance of the TOF-SIMS spectrometer will be
discussed.

Keywords: HIM; SIMS

Related publications

  • Invited lecture (Conferences)
    Zakopane School of Physics, 24.5.2019, Zakopane, Polen

Permalink: https://www.hzdr.de/publications/Publ-30527
Publ.-Id: 30527


In-situ experiments and characterization in the Helium Ion Microscope

Hlawacek, G.

In-situ experiments in the HIM

Keywords: HIM

Related publications

  • Open Access Logo Invited lecture (Conferences)
    Ion beams for future technologies 2019, 2.4.2019, Dubrovnik, Kroatien

Permalink: https://www.hzdr.de/publications/Publ-30526
Publ.-Id: 30526


Avoiding amorphization in silicon nano structures

Hlawacek, G.; Xu, X.; Engelmann, H.-J.; Heinig, K.-H.; Möller, W.; Ahmed, G.; Raluca, T.; Bischoff, L.; Prüfer, T.; Hübner, R.; Facsko, S.; Borany, J.

Helium Ion Microscopy (HIM) [1, 2] is best known for its high resolution imaging capabilities of both
conductive as well as insulating samples. However, since the introduction of Ne as an imaging gas for the
gas field ion source (GFIS) an increasing number of nano-fabrication applications are realized. While
the use of Neon as an imaging gas results in a somewhat lower lateral resolution (1.8 nm for 25 keV
Ne compared to 0.5 nm for 30 keV He) the user usually benefits from the much higher cross section for
nuclear stopping. The latter results in a larger number of sputtered atoms and bonds broken directly
by small impact parameter collisions.
After a brief introduction of the technique I will present results obtained using direct write milling low
fluence ion beam irradiation and ion beam based mixing. In all three cases the electronic or magnetic
properties of the target material will be altered at the nano-scale in a controlled way to achieve new
functionality. The examples comprise
∙ The fabrication of semiconducting graphene nano-ribbons by direct milling [3]
∙ The fabrication of a lateral spin valve structure using low fluence ion irradiation [4]
∙ The formation of individual 3 nm Si clusters for a room temperature single electron transistor [5]
For all presented examples the critical length scale of the nanostructure is smaller or in the range of
collision cascade. This size regime can not be accessed with traditional broad beam based ion irradiation
and holds many promises but also challenges that need to be overcome to enable new device concepts
and new functional materials on the nano-scale.
This work is supported by the European Union’s H-2020 research project ‘IONS4SET’ under Grant
Agreement No. 688072

Keywords: HIM; modification

Related publications

  • Lecture (Conference)
    DPG Frühjahrstagung, 3.4.2019, Regensburg, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30525
Publ.-Id: 30525


Spatially resolved materials modification using Helium Ion Microscopy

Hlawacek, G.

Helium Ion Microscopy (HIM) [1, 2] is best known for its high resolution imaging capabilities of both
conductive as well as insulating samples. However, since the introduction of Ne as an imaging gas for the
gas field ion source (GFIS) an increasing number of nano-fabrication applications are realized. While
the use of Neon as an imaging gas results in a somewhat lower lateral resolution (1.8 nm for 25 keV
Ne compared to 0.5 nm for 30 keV He) the user usually benefits from the much higher cross section for
nuclear stopping. The latter results in a larger number of sputtered atoms and bonds broken directly
by small impact parameter collisions.
After a brief introduction of the technique I will present results obtained using direct write milling low
fluence ion beam irradiation and ion beam based mixing. In all three cases the electronic or magnetic
properties of the target material will be altered at the nano-scale in a controlled way to achieve new
functionality. The examples comprise
∙ The fabrication of semiconducting graphene nano-ribbons by direct milling [3]
∙ The fabrication of a lateral spin valve structure using low fluence ion irradiation [4]
∙ The formation of individual 3 nm Si clusters for a room temperature single electron transistor [5]
For all presented examples the critical length scale of the nanostructure is smaller or in the range of
collision cascade. This size regime can not be accessed with traditional broad beam based ion irradiation
and holds many promises but also challenges that need to be overcome to enable new device concepts
and new functional materials on the nano-scale.
This work is supported by the European Union’s H-2020 research project ‘IONS4SET’ under Grant
Agreement No. 688072

Keywords: Helium ion microscopy; materials modification

Related publications

  • Lecture (others)
    Institutsseminar, 31.01.2019, Strassbourg, Frankreich
  • Invited lecture (Conferences)
    EIPBN, 30.5.2019, Minneapolis, USA

Permalink: https://www.hzdr.de/publications/Publ-30524
Publ.-Id: 30524


Mapping of Magnetic Metastable States in Synthetic Antiferro- and Ferrimagnets with Perpendicular Magnetic Anisotropy

Salikhov, R.; Samad, F.; Koch, L.; Böhm, B.; Hellwig, O.

Magnetic multilayers (MLs) with perpendicular magnetic anisotropy (PMA), such as Co/Pt or
Co/Pd, are the host materials for a variety of metastable magnetic configurations, e.g. aligned or labyrinth
stripe domains, bubble domains and their mixtures. The magnetic morphology at remanence mostly depends
on the specific demagnetization routine using an external magnetic field [1], whereas the characteristic size of
the magnetic objects (domain period or bubble radius) is mostly determined by the design parameters of the
magnetic MLs (e.g. the thickness of Co layer, periodicity and the number of repeats X) [1,2]. Interleaving the
Co/Pt blocks by Ru or Ir layers, which promote antiferromagnetic (AF) interlayer coupling between PMA ML
blocks, results in a class of artificial magnetic structures, known as synthetic antiferromagnets (SAFs) with
PMA. The AF interlayer exchange energy alters the typical energy balance, thus modifying the morphology
and characteristic size of magnetic domain states in PMA SAFs [1]. Stabilisation of magnetic bubble domain
states in SAFs is of particular practical interest [3], whereas other new magnetic configurations are of interest
for fundamental research. Here we present the mapping of magnetic states in SAFs for different
demagnetization protocols and ML parameters by means of monitoring the remanent magnetization Mr during
the AC or DC demagnetization process itself and performing magnetic force microscopy (MFM) imaging at the
intermediate states of interest (Fig. 1). The aligned stripe domain state is characterised by almost zero Mr,
whereas bubble domains [4] and mixed states (Fig. 1) manifest themselves by an enhanced Mr. The magnetic
states for SAFs with tunable parameters such as Co thickness and repetition number X will be presented. We
will also discuss the magnetic behaviour in synthetic ferrimagnets, where the two ML block sub-lattices have
different magnetic moments.
References: [1] O. Hellwig, A. Berger, J. B. Kortright, JMMM, Vol. 319, p.13-55 (2007)
[2] I. Lemesh, F. Büttner, G. S. D. Beach, Phys. Rev. B, Vol. 95, p.174423 (2017)
[3] K. Chesnel, A. S. Westover, C. Richards, Phys. Rev. B, Vol. 98, p.224404 (2018)
[4] A. Hubert, R. Schäfer, Magnetic Domains, Springer Berlin (2009)

  • Lecture (Conference)
    64th Annual Conference on Magnetism and Magnetic Materials (MMM 2019), 04.-08.11.2019, Las Vegas, Nevada, USA

Permalink: https://www.hzdr.de/publications/Publ-30523
Publ.-Id: 30523


ESUO - The European Synchrotron and FEL User Organisation: Aims and activities

Arčon, I.; Arikan, P.; Bittencourt, C.; Boscherini, F.; Braz Fernandes, F. M.; Brooks, N.; Casu, B.; D'Astuto, M.; Feiters, M.; Froideval, A.; Granroth, S.; Gross, S.; Gutt, C.; Hase, T.; Jablonska, K.; Jergel, M.; Khan, A.; Kirm, M.; Kokkinidis, M.; Kövér, L.; Lamba, D.; Larsen, H. B.; Lechner, R. T.; Le Hir, R.; Logan, D. T.; López, O.; Lorentz, K.; Mariani, C.; Marinkovic, B.; Mcguinness, C.; Meedom Nielsen, M.; Micetic, M.; Mickevicius, S.; Mikulík, P.; Petukhov, A.; Pietsch, U.; Pokroy, B.; Purans, J.; Renault, L.; Santoro, G.; Shivachev, B.; Stangl, J.; Tromp, M.; Vankó, G.; Blasetti, C.; Freire Anselmo, A. S.; Grobosch, M.; Helm, M.; Schramm, B.; Vollmer, A.

The European Synchrotron and free-electron laser User Organisation (ESUO) established in 2010 represents about 22.000 users. It is composed of 30 member countries. Our vision is to support a thriving (European) synchrotron and FEL user community with equal opportunities of access and participation for all scientists, based solely on the scientific merit of their ideas.

  • Poster
    EMFL User Meeting 2019, 25.06.2019, Warsaw, Poland

Permalink: https://www.hzdr.de/publications/Publ-30521
Publ.-Id: 30521


Exploiting Hysteresis in a Multicaloric Cooling Cycle

Gottschall, T.

für den Vortrag hat keine inhaltliche Kurzfassung vorgelegen

  • Invited lecture (Conferences)
    Annual Conference on Magnetism and Magnetic Materials 2019, 04.-08.11.2019, Las Vegas, USA

Permalink: https://www.hzdr.de/publications/Publ-30520
Publ.-Id: 30520


Multicaloric materials and their characterization

Gottschall, T.

für diesen Vortrag hat keine inhaltliche Kurzfassung vorgelegen

  • Invited lecture (Conferences)
    Ruhr Symposium 2019, 09.10.2019, Duisburg, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30519
Publ.-Id: 30519


The activities of the European Synchrotron and FEL User Organisation for even brighter European Photon Science

Pietsch, U.; Arčon, I.; Arikan, P.; Bittencourt, C.; Boscherini, F.; Braz Fernandes, F. M.; Brooks, N.; Casu, B.; D'Astuto, M.; Feiters, M.; Froideval, A.; Granroth, S.; Gross, S.; Gutt, C.; Hase, T.; Jablonska, K.; Jergel, M.; Khan, A.; Kirm, M.; Kokkinidis, M.; Kövér, L.; Lamba, D.; Larsen, H. B.; Lechner, R. T.; Le Hir, R.; Logan, D. T.; López, O.; Lorentz, K.; Mariani, C.; Marinkovic, B.; Mcguinness, C.; Meedom Nielsen, M.; Micetic, M.; Mickevicius, S.; Mikulík, P.; Petukhov, A.; Pokroy, B.; Purans, J.; Renault, L.; Santoro, G.; Shivachev, B.; Stangl, J.; Tromp, M.; Vankó, G.; Blasetti, C.; Freire Anselmo, A. S.; Grobosch, M.; Helm, M.; Schramm, B.; Vollmer, A.

The European Synchrotron and FEL User Organisation (ESUO) represents about 22 000 users of the European synchrotron radiation (SR) and Free-Electron Laser (FEL) facilities, which offer various kinds of experiments ranging from physics over life sciences up to cultural heritage. Established in 2010, ESUO is composed of national delegates from 30 European member states and associated countries and is headed by an executive board of eight members. Our vision is to support a thriving (European) synchrotron and FEL user community with equal opportunities of access and participation for all scientists, based solely on the scientific merit of their ideas.

  • Invited lecture (Conferences)
    ESUO Regional Workshop at PHOTONICA 2019 Conference, 28.08.2019, Belgrade, Serbia

Permalink: https://www.hzdr.de/publications/Publ-30518
Publ.-Id: 30518


Preparation and Characterization of Solar Thermal Absorbers by Nanoimprint Lithography and Sputtering

Mitteramskogler, T.; Haslinger, M. J.; Wennberg, A.; Fernandez Martínez, I.; Muehlberger, M.; Krause, M.; Guillén, E.

Selective solar absorbers comprised of plasmonic materials offer great flexibility in design along with a highly promising optical performance. However, the nanopattern generation, typically done with electron beam writing, is a very time-intensive process. In this work, we present a fast, scalable, and flexible method for the fabrication of plasmonic materials by the combination of a deposition mask prepared by nanoimprint lithography and thin film deposition by magnetron sputtering. The fabrication process was first performed on silicon wafer substrates using AFM and SEM measurements to calibrate the deposition time, determine maximal deposition height, and characterize samples. Afterwards, the process was transferred to polished Inconel NiCr-alloy substrates used in high temperature solar absorbers. To investigate the adhesion properties of the nanostructure on the substrate, two different deposition methods were investigated: DC magnetron sputtering and High Power Impulse Magnetron Sputtering (HiPIMS).

Keywords: Solar absorbers; nanoimprint lithography; HiPIMS

Related publications

  • Contribution to proceedings
    2019 MRS Spring Meeting & Exhibition, 22.-26.04.2019, Phoenix, USA
    MRS Advances 4(2019)35, 1905-1911: Cambridge
    DOI: 10.1557/adv.2019.285
  • Lecture (Conference)
    2019 MRS Spring Meeting & Exhibition, 22.-26.04.2019, Pheonix, USA

Permalink: https://www.hzdr.de/publications/Publ-30516
Publ.-Id: 30516


High temperature in-air stability of solar absorber coatings based on aluminium titanium oxynitride nanocomposites

Heras, I.; Krause, M.; Rincón, G.; Guillén, E.; Azkona, I.; Lungwitz, F.; Munnik, F.; Escobar Galindo, R.

One of the major challenges in Concentrating Solar Power (CSP) implies an increase of the working temperature of the solar receiver. In particular, current central tower systems operate at maximum temperatures of 550 ºC mainly due to the severe degradation that the state of the art absorber paints (i.e. Pyromark®) suffer at higher temperatures. In previous works [1,2] aluminum titanium oxynitrides AlyTi1-y(OxN1-x) were shown to be excellent candidate materials for solar selective coatings (SSC). These results confirmed that the designed SSCs based on materials withstand breakdown at 600 ºC in air after 900 hours of thermal cycling.
In this paper we discuss the high temperature (up to 700ºC) stability in air of a solar absorber coating based on AlyTi1-y(OxN1-x) deposited by cathodic vacuum arc (CVA) at higher working pressure (P = 2.1 Pa) than those discussed in [1] and [2]. The composition, morphology and microstructure of the films were characterized by ion beam analysis, scanning and transmission electron microscopy and X-ray diffraction. The optical properties were determined by ellipsometry and spectrophotometry (UV-Vis-NIR, FTIR). The microstructural and morphological characterization shows the formation of a solid solution of AlTiN crystalline nanoparticles embedded in an amorphous Al2(O, N)3 matrix. This particular microstructure results in a coating with a high absorption coefficient within the whole wavelength range of interest (0,3 to 25 um) as modeled by spectroscopic ellipsometry. Hence, this single layer absorber shows a solar absorptance, α, of 92% and an emissivity, εRT, of 70%. The addition of an antireflective Al2O3 layer and post deposition thermal treatments improved the optical properties of the absorber to better values (α=96% and εRT=60%) than those of Pyromark®. The thermal stability in air of the absorber was firstly analyzed by cyclic heating tests, showing no degradation after 300h of cycles in air at 700ºC. Subsequently, the samples were tested in a solar furnace at 650 °C and 800 ºC for 12 hours at environmental conditions. Therefore, this absorber coating can be a feasible alternative to absorber paints for next generation of concentrated solar power plants operating at high temperature.
[1] I. Heras et al., Sol. Energy Mat. Solar Cells, 176, 81-92 (2018)
[2] R. Escobar-Galindo et al., Sol. Energy Mat. Solar Cells, 185, 183-191 (2018)

Keywords: Solar selective coatings; thermal stability; optical properties; concentrated solar power; optical simulation; oxynitrides

Related publications

  • Lecture (Conference)
    2019 MRS Spring Meeting & Exhibition, 22.-26.04.2019, Phoenix, USA

Permalink: https://www.hzdr.de/publications/Publ-30515
Publ.-Id: 30515


ESUO - The European Synchrotron and FEL User Organisation

Arčon, I.; Arikan, P.; Bittencourt, C.; Boscherini, F.; Braz Fernandes, F. M.; Brooks, N.; Casu, B.; D'Astuto, M.; Feiters, M.; Froideval, A.; Granroth, S.; Gross, S.; Gutt, C.; Hase, T.; Jablonska, K.; Jergel, M.; Khan, A.; Kirm, M.; Kokkinidis, M.; Kövér, L.; Lamba, D.; Larsen, H. B.; Lechner, R. T.; Le Hir, R.; Logan, D.; López, O.; Lorentz, K.; Mariani, C.; Marinkovic, B.; Mcguinness, C.; Meedom Nielsen, M.; Micetic, M.; Mickevicius, S.; Mikulík, P.; Petukhov, A.; Pietsch, U.; Pokroy, B.; Purans, J.; Renault, L.; Santoro, G.; Shivachev, B.; Stangl, J.; Tromp, M.; Vankó, G.; Freire Anselmo, A. S.; Blasetti, C.; Grobosch, M.; Helm, M.; Schramm, B.; Vollmer, A.

The European Synchrotron and free-electron laser User Organisation (ESUO) established in 2010 represents about 22.000 users. It is composed of 30 member countries. Our vision is to support a thriving (European) synchrotron and FEL user community with equal opportunities of access and participation for all scientists, based solely on the scientific merit of their ideas.

  • Poster
    11th Joint BER II and BESSY II User Meeting, 04.-06.12.2019, HZB, Germany

Permalink: https://www.hzdr.de/publications/Publ-30514
Publ.-Id: 30514


Cluster tool for in situ processing and comprehensive characterization of energy materials at high temperatures

Krause, M.; Wenisch, R.; Lungwitz, F.; Heras, I.; Janke, D.; Azkona, I.; Escobar Galindo, R.; Gemming, S.

In situ processing and comprehensive characterization is essential for design and development of materials used and processed at high-temperatures. Here, a new cluster tool for processing and depth-resolved compositional, structural and optical characterization of layered
materials with thicknesses ranging from sub-nm to 1 μm at temperatures of -100 to 1000 °C is described [1]. The implemented techniques comprise
magnetron sputtering, ion irradiation, Rutherford backscattering spectrometry, Raman spectroscopy and spectroscopic ellipsometry. The combination of techniques enables sample processing by scalable, clean, waste-free, and industry-relevant technologies, quantitative depth-profiling for elements with Z ≥ 6, structural and chemical characterization, sensitivity and nm-precise thickness and optical information for single layers, multilayers and composites. In this study, the cluster tool was used for i) metal-induced crystallization with layer-exchange of a-Si/ Ag layer stacks, and ii) for hightemperature characterization of two types of solar-selective coatings for concentrated solar power (CSP), namely Al Ti (O N )-based single and multilayers [2, 3] and an n-type doped solar-selective transparent conductive oxide [4]. Starting with an a-Si/ Ag bilayer stack, metal-induced silicon crystallization with partial layer exchange occurs at 540 °C. The final stack is approximately described by the sequence crystalline Si (c-Si)/ Ag/ c-Si. All the layers contain minor fractions of the other element. Moreover, the Si volume fraction comprises approximately 10 % of amorphous Si. For the CSP coatings, no compositional and structural changes were found up to a maximum temperature of 840 °C in vacuum. Both types of solar-selective coatings thus represent promising materials for the next generation of CSP technology.
[1] R. Wenisch et al., Anal. Chem. 90, 7837-7824 (2018)
[2] I. Heras et al., Sol. Energy Mat. Solar Cells, 176, 81-92 (2018)
[3] R. Escobar-Galindo et al., Sol. Energy Mat. Solar Cells, 185, 183-191 (2018)
[4] F. Lungwitz et al., submitted (2018)
Financial support by the EU, grant No. 645725, project FRIENDS , and the HGF via the W3 program (S.G.) is gratefully acknowledged.

Keywords: Cluster tool; in situ processing and analysis; high temperature; Rutherford backscattering; Raman spectroscopy; ellipsometry; metal-induced crystallization

Related publications

  • Lecture (Conference)
    2019 MRS Spring Meeting & Exhibition, 22.-26.04.2019, Phoenix, USA

Permalink: https://www.hzdr.de/publications/Publ-30511
Publ.-Id: 30511


Acoustic signatures of the phase transitions in the antiferromagnet U2Rh2Sn

Gorbunov, D.; Andreev, A. V.; Ishii, I.; Prokes, K.; Suzuki, T.; Zherlitsyn, S.; Wosnitza, J.

We report on ultrasound measurements in a single crystal of the antiferromagnet U2Rh2Sn as a function of temperature and magnetic field. We find pronounced anomalies in the sound velocity at the Néel temperature, 25 K, and at the field-induced spin-flop-like transition at 22.5 T, which points to a strong magnetoelastic coupling. Additionally, we find that in the paramagnetic regime the temperature dependence of the magnetic susceptibility and the field dependences of the magnetization and sound velocity of transverse acoustic waves can be well described assuming a localized character of the 5 f electrons. Using this premise, the crystal-electric-field scheme of U2Rh2Sn has been determined.

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Permalink: https://www.hzdr.de/publications/Publ-30510
Publ.-Id: 30510


Easy-plane magnetic anisotropy in layered GdMn2Si2 compound with easy-axis magnetocrystalline anisotropy

Gerasimov, E. G.; Terentev, P. B.; Gubkin, A. F.; Fischer, H. E.; Gorbunov, D.; Mushnikov, N. V.

Magnetic properties and magnetic structures of layered GdMnSi2 compound were studied using quasisingle crystal, high magnetic fields up to 520 kOe, and neutron powder diffraction experiment designed for high absorbent systems. It was shown that GdMn2Si2 has strong easy plane type magnetic anisotropy at temperatures TGd < 52 K at which Gd atoms are magnetically ordered. At temperatures 52 K < T < 453 K, the compound has antiferromagnetic ordering of Mn layers and easy axis type magnetic anisotropy with the easy axis directed along the tetragonal c-axis. The exchange-induced in-plane magnetic anisotropy of layered GdMn2Si2 at low temperatures arises to prevent magnetic frustration in Gd layers. Magnetic properties of GdMn2Si2 at temperatures below 52 K can be described within a threesublattice model based on the Yafet-Kittel approximation.

Permalink: https://www.hzdr.de/publications/Publ-30509
Publ.-Id: 30509


Wayforlight: The Catalogue of European Light Sources

Blasetti, C.; Andrian, I.; Billè, F.; Coghetto, E.; Deiuri, S.; Favretto, D.; Turcinovich, M.; Pugliese, R.; Osmenaj, E.; Appleby, G.; Froideval, A.; Pietsch, U.; Sanchez, A.; Valls Vidal, N.; Mitchell, E.; Rabhi, N.; Aogaki, S.; Kasik, Z.; Canova, F.; Gliksohn, F.; Stozno, D.; Michel, J.; Normand, D.; Brancaleon, R.; Paro, G.; Tinta, M.; Zotti, D.

Wayforlight.eu is the gateway to finding the most suitable instruments for experiments with synchrotron, FEL, and laser light sources. The portal's main asset is a detailed searchable catalogue of facilities, beamlines, and instrumentation available at European light sources. Thanks to its advanced search tools, a visitor can filter beamlines by scientific discipline, by technique, but also by energy range or sample type.

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Permalink: https://www.hzdr.de/publications/Publ-30507
Publ.-Id: 30507


REELS and Auger spectroscopy study of layers exchange in C/Ni-bilayer system

Vretenár, V.; Janke, D.; Vanco, L.; Krause, M.

New experimental methods for synthesis of low dimensional carbon structures still attract considerable attention, many of them based on catalytically driven processes.
In this contribution we present REELS and Auger spectroscopy study of Ni-induced
layer exchange in Ni/C-bilayer thin film system. EELS spectroscopy in reflected
mode (REELS) and Auger electron spectroscopy (AES) were employed to characterize
the structure, homogeneity and quality of carbon and nickel film (each having
thickness around 50 nm) and their interface between, before and after thermal annealing
at 700 °C. AES mapping and depth profiling revealed a layer exchange
between the layers after thermal annealing, accompanied by partial nickel diffusion
into MgO substrate. REELS analysis showed successful structural transformation
of initially amorphous carbon layer into compact graphitic one. The transformed carbon
layer has a slightly rippled surface as confirmed by topological backscattered
electron imaging.

Keywords: Metal-induced crystallization; turbostratic carbon; electron spectroscopy

Related publications

  • Poster
    International Winterschool on Electronic Properties of Novel Materials - Molecular Nanostructures, 09.-16.03.2019, Kirchberg, Österreich

Permalink: https://www.hzdr.de/publications/Publ-30506
Publ.-Id: 30506


Time- and temperature-resolved in situ investigation of the metal-induced crystallization of amorphous carbon thin films

Janke, D.; Julin, J.; Hübner, R.; Gemming, S.; Rafaja, D.; Krause, M.

The graphitization of amorphous carbon in thin film stacks with Ni was investigated in situ as a function of the initial stacking order, temperature and time by Rutherford backscattering spectrometry and Raman spectroscopy. Four different bilayer and triple layer stacks were exposed to heating ramps up to 700 °C. The graphitization occurred simultaneously with a layer exchange (LE) and was completed during the applied heating ramp. The temperature-resolved measurements allowed the determination of the onset temperatures and transition rates for the respective stacking order. Finally, the activation energies for the graphitization of the amorphous carbon were estimated for both LE directions. In combination with thermodynamic calculations,
this in situ study allowed to identify metal-induced crystallization with LE via wetting and diffusion along grain boundaries as mechanism responsible for the graphitization of amorphous carbon thin films in contact with Ni, instead of bulk dissolution/precipitation. The proposed model can potentially be used to estimate the catalytic transformation of group 14 elements in contact with transition metals.

Keywords: Cluster Tool; in situ processing and analysis; layer exchange; turbostratic carbon

Related publications

  • Poster
    International Winterschool on Electronic Properties of Novel Materials - Molecular Nanostructures, 09.-16.03.2019, Kirchberg, Österreich

Permalink: https://www.hzdr.de/publications/Publ-30505
Publ.-Id: 30505


Impact of low energy ion beams on the properties of rr-P3HT films

Kislyuk, V.; Kotrechko, S.; Trachevskij, V.; Melnyk, A.; Pud, A.; Ogurtsov, N.; Noskov, Y.; Osiponok, M.; Lytvyn, P.; Dzyazko, Y.; Nierobisch, F.; Schneider, A.; Ludewig, F.; Akhmadaliev, S.; Aniol, R.; Kentsch, U.; Krause, M.; Facsko, S.

Two types of ions (fluorine and titanium) are implanted into films of regio-regular poly(3-hexylthiophene-2,5-diyl) (rr-P3HT) spin-coated on glass substrates with subsequent annealing in argon atmosphere to modify their electrical properties and structure. The ion energy and fluence were within 0.2–40 keV and 10¹³–10¹⁵ cm⁻² respectively. The dc resistance enhances after the intensive ion beam treatment while the ac impedance decreases. Ti ion implantation with 40 keV energy and 10¹⁴ cm⁻² fluence induces decrease of the ac impedance by almost two orders of magnitude and appearance of the molecular hydrogen features in ¹H NMR spectrum. The UV–VIS spectra of the films are blue shifted after their exposal to the ion beams, which correlates with the presence of oxygen. The ratio of the oxygen to carbon peak intensities (O1s/C1s) in the XPS spectra is proposed as a measure for the local partial disturbance of the film. EPR spectra demonstrate formation of the paramagnetic states with g factor <2, which is accompanied with the down-field shift of the NMR spectrum. The ion beams are found to have no significant etching effect as per results of the film thickness measurements and AFM images.

Keywords: Ion implantation; rr-P3HT; Doping; Resistance; Ac impedance; Organic electronics

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Permalink: https://www.hzdr.de/publications/Publ-30504
Publ.-Id: 30504


Directionality and energetics of the metal-induced crystallization of amorphous carbon thin films

Janke, D.; Wüstefeld, C.; Julin, J. A.; Hübner, R.; Grenzer, J.; Gemming, S.; Rafaja, D.; Krause, M.

The catalytic graphitization with layer exchange (LE) of amorphous carbon in thin film stacks with Ni was investigated as a function of the initial stacking order. Bilayer and triple layer stacks were exposed to heating ramps up to 700 °C. Raman spectroscopy showed the formation of a layered graphitic structure after the annealing.
During outwards LE, as C is transported towards the sample surface, a smooth layer with graphitic planes parallel to the interface with the substrate has formed through a 2D growth. A significant restructuring of the Ni layer appeared during inwards LE, as C is transported towards the substrate. Here, the fragmentation of the Ni layer, as well as the regions with turbulence-like and folding defects indicated a 3D growth.
The degree of LE, quantified by ion beam analysis, is 95 % and 80 % for the outand inwards direction, respectively. Based on the calculation of surface and interface energies of the initial and final states, thermodynamic estimations pointed to the wetting of Ni grain boundaries by C atoms as the initial driving force for the LE and allowed a consistent understanding of the LE directionality and of the final thin film microstructure.

Related publications

  • Poster
    International Winterschool on Electronic Properties of Novel Materials - Molecular Nanostructures, 09.-16.03.2019, Kirchberg, Österreich
  • Lecture (Conference)
    MRS Spring Meeting & Exhibition, 22.-26.04.2019, Phoenix, USA

Permalink: https://www.hzdr.de/publications/Publ-30503
Publ.-Id: 30503


Theory and simulation on nonlinear spin-wave dynamics in magnetic vortices

Körber, L.; Schultheiß, K.; Hula, T.; Verba, R.; Kakay, A.; Hache, T.; Ivanov, B.; Faßbender, J.; Schultheiß, H.

One of the fascinating qualities of spin waves (or magnons), which are the elementary excitations in magnetically ordered substances, is their nonlinear behavior at moder- ate excitation powers. This makes spin waves not only an attractive model system to study general nonlinear systems, but it also provides a way to utilize nonlinear dynamics in possible technical applications. In a ferromagnetic nano disk which is magnetized in the vortex state, the spin-wave modes meet strict boundary conditions and therefore inherit a discrete spectrum. When driven with a large enough excitation field, they can decay into other spin-wave modes within well-defined channels due to a nonlinear process called three-magnon scattering [1]. The aim of this project is to explore this phenomenon within nonlinear spin-wave theory and by means of micromagnetic simulations.
For this purpose, first the linear dynamics are mapped out and the possible scattering channels are predicted. The stability of these channels with respect to static external fields is studied. Within this context, exotic spin-wave modes which arise in a broken cylindrical symmetry are found. Moreover, a model to predict the temporal evolution of the spin-wave modes is developed within the classical Hamiltonian formalism for nonlinear spin-wave dynamics. Together with micromagnetic simulations, this model is applied in order to study the power-dependence of three-magnon scattering as well as to uncover a phenomenon called stimulated three-magnon scattering, which may allow for an integration of this nonlinear pro- cess in magnonics circuits. The results are compared with Brillouin light-scattering experiments which were conducted prior to this thesis or were motivated by it. Financial support of within DFG programme SCHU 2922/1-1 and KA 5069/1-1 is acknowledged.

Keywords: nonlinear; spin wave; magnon; vortex; three-magnon scattering; BLS; micromagnetic simuations; micromagnetism

  • Poster
    710. WE-Heraeus-Seminar: Spin Transport in Complex Magnetic Structures, 07.-10.01.2020, Physikzentrum Bad Honnef, Germany

Permalink: https://www.hzdr.de/publications/Publ-30502
Publ.-Id: 30502


Integration of 1D and 2D Materials into Functional Structures and Devices

Georgiev, Y.

In this talk I will make a brief overview of our activities for integration of different 1D and 2D materials into functional structures and devices.

I will first present the work on fabrication, processing and application of group IV semiconductor nanowires (NWs). These include top-down fabricated Si, SiGe and Ge NWs as well as bottom-up grown Si, Ge1-xSnx with x = 0.07-0.1 and GaAs/In0.45Ga0.55As NWs. I will also consider the innovative devices that we are targeting: junctionless nanowire transistors (JNTs), reconfigurable field effect transistors (RFETs) and band-to-band tunnel FETs (TFETs).

I will next discuss our activities for fabrication and characterisation of FETs based on 2D heterostructures. As examples I will show FETs fabricated on hBN-encapsulated InSe, a material with attractive properties but very unstable in ambient atmosphere, as well as TFETs fabricated on hBN/MoS2/WSe2/graphene heterostructures.

Finally, I will pay some attention to our work on using DNA origami templates for the fabrication of functional structures with the outlook to the application of DNA origami for self-assembly of electronic circuits. In particular, I will show fabrication of conducting metallic NWs using templates of DNA nanotubes, nanosheets and nanomoulds as well as incorporation into them of molecules and semiconducting nanoparticles for enhanced electronic functionality.

Keywords: 1D materials; 2D materials; semiconductor nanowires; DNA origami; transition metal dichalcogenides; top-down nanofabrication; bottom-up nanofabrication; junctionless nanowire transistors; reconfigurable field effect transistors; band-to-band tunnel field effect transistors

Related publications

  • Invited lecture (Conferences)
    Meeting at the Advanced Microelectronic Centre Aachen (AMICA), AMO gGmbH, 02.-03.12.2019, Aachen, Germany

Permalink: https://www.hzdr.de/publications/Publ-30499
Publ.-Id: 30499


Ion beam implanted Germanium nanowires

Echresh, A.; Xie, Y.; Prucnal, S.; Rebohle, L.; Georgiev, Y.

Germanium (Ge) is a promising high mobility channel material for future nanoelectronics. Materials with high carrier mobility can enable increased integrated circuit functionality or reduced power consumption. Hence, Ge based nanoelectronic devices could offer improved performance at reduced power consumption compared to Si electronics [1].

The introduction of impurity atoms allows the tuning of the electrical properties of the semiconductor material. Ion beam implantation is an industrial standard for semiconductor's doping as it can incorporate single ion species with a single energy in a highly controlled fashion. However, the destructive nature of ion beam implantation requires a crystal recovery step such as an annealing process [2].

In this work, Germanium-on-insulator (GeOI) substrates were doped with phosphorous (P) using ion beam implantation followed by flash lamp annealing (FLA). During FLA process the implanted layer recrystallized and P was electrically activated. Then Ge nanowires were fabricated using electron beam lithography (EBL) and inductively coupled plasma (ICP) etching. Raman spectra showed the amorphisation of Ge structure after implantation and good recovery after FLA (Fig. 1). Rutherford backscattering spectrometry (RBS) measurement in random (R) and channeling (C) modes (Fig. 2) were used to verify the crystal quality of Ge layer before and after FLA. As one can see, the yield intensity of the channeling mode was increased after implantation, which can be related to amorphisation of the top Ge layer. Also, the yield peak of flashed GeOI has a good match with unimplanted counterpart, which shows the good recrystallization during FLA. Moreover, we designed Hall effect measurement configuration for single Ge nanowires (Fig. 3) to determine the carrier mobility and carrier concentration. The results of these measurements will be shown at the conference [3,4]. The goal is to fabricate p-n junction along the Ge nanowires and use it as an infrared sensor.

Keywords: Ion beam implantation; Flash lamp annealing; Doping; p-n junction; Infrared sensor

Related publications

  • Poster
    45th International Conference on Micro & Nano Engineering (MNE), 23.-26.09.2019, Rhodes, Greece
  • Poster
    NanoNet International Conference 2019, 08.-11.10.2019, Dresden, Germany

Permalink: https://www.hzdr.de/publications/Publ-30498
Publ.-Id: 30498


Phosphorous doped Germanium nanowires

Echresh, A.; Jazavandi Ghamsari, S.; Georgiev, Y.; Rebohle, L.

Germanium (Ge) is a promising high mobility channel material for future nanoelectronic devices with a lower effective charge carrier mass than Silicon (Si) and higher electron and hole mobility. Materials with high carrier mobility can enable increased integrated circuit functionality. Hence, Ge based nanoelectronic devices could offer improved performance at reduced power consumption compared to Si electronics. In this work, Ge nanowires were fabricated using electron beam lithography (EBL) and inductively coupled plasma (ICP) etching. Then ion beam implantation was used to introduce phosphorous (P) dopant atoms into the Ge nanowires. Afterwards, flash lamp annealing (FLA) was applied to recover the crystal structure of the Ge nanowires and activate the dopant atoms. Micro-Raman spectroscopy spectra showed that by increasing the fluence of ion implantation, the peak of optical phonon mode in Ge was broadened asymmetrically which shows that dopant atoms are electrically activated. Moreover, we are designing Hall Effect measurement configurations for single Ge nanowires to determine their mobility and carrier concentrations.

Related publications

  • Poster
    DPG Spring Meeting 2019, 31.03.-05.04.2019, Regensburg, Germany

Permalink: https://www.hzdr.de/publications/Publ-30497
Publ.-Id: 30497


Erbium-ion implantation of single- and nano-crystalline ZnO

Cajzl, J.; Nekvindova, P.; Jeníčková, K.; Jagerová, A.; Malinský, P.; Remeš, Z.; Neykova, N.; Chang, Y.-Y.; Oswald, J.; Kentsch, U.; Macková, A.

This paper reports on the results of Er+ ion implantation into various ZnO structures - standard single crystal c-plane (0001) ZnO, nanostructured thin films and nanorods. Er+ ions were implanted using an ion implantation energy of 400 keV and implantation fluences in the range of 5×1014 to 5×1015 ions/cm2. Er concentration depth profiles and the degree of crystal damage were measured using Rutherford backscattering spectrometry (RBS) and RBS/channelling (RBS/C). Additionally, Raman spectroscopy was used to analyse structural modifications of the prepared samples. The main focus was placed on the luminescence properties of various ZnO structures. The results showed that the characteristic bands of ZnO, i.e. near-band-edge (NBE) luminescence and deep-level emission (DLE) - that can be influenced by the excitation wavelength - appeared in the spectra of single crystals and nanorods. The characteristic luminescence bands of erbium ions in the NIR region appeared in ZnO single-crystal samples and nano-crystalline films.

Keywords: ZnO; nanocrystalline thin films; nanorods; erbium; ion implantation; luminescence

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Permalink: https://www.hzdr.de/publications/Publ-30496
Publ.-Id: 30496


Ion beam implanted Germanium nanowires fabricated by using electron beam lithography

Echresh, A.; Jazavandi Ghamsari, S.; Helm, M.; Rebohle, L.; Georgiev, Y.

Germanium (Ge) is a promising high mobility channel material for future nanoelectronic devices with a lower effective charge carrier mass than Silicon (Si), which results in a higher electron (×2) and hole (×4) mobility. Materials with high carrier mobility can enable increased integrated circuit functionality or reduced power consumption. Hence, Ge based nanoelectronic devices could offer improved performance at reduced power consumption compared to Si electronics. Doping or the introduction of impurity atoms allows the tuning of the electrical properties of the semiconductor material. Ion beam implantation is an industrial standard for semiconductor's doping as it can incorporate single ion species with a single energy in a highly controlled fashion. The destructive nature of ion implantation doping due to the deposited energy and resultant cascade of recoils within the nanowire volume requires a crystal recovery step such as an annealing process. In this work, Ge nanowires were first fabricated using electron beam lithography (EBL) and inductively coupled plasma (ICP) etching. Then ion beam implantation was used to introduce phosphorous (P) dopant atoms into Ge nanowires. Afterwards, flash lamp annealing (FLA) was applied to recover the crystal structure of Ge nanowires and activate the dopant atoms. Micro-Raman spectroscopy spectra showed that, by increasing the fluency of ion implantation, the optical phonon mode of Ge peak was broadened asymmetrically. This is related to the Fano effect and shows that dopant atoms are placed in substitutional positions and are electrically activated. Moreover, we are designing three- and four-probe Hall Effect measurement configurations for single Ge nanowires to determine their mobility and carrier concentrations.

Related publications

  • Poster
    Towards Reality in Nanoscale Materials X, 14.-16.02.2019, Levi, Finland

Permalink: https://www.hzdr.de/publications/Publ-30495
Publ.-Id: 30495


Implementation of a cryogenic hydrogen jet target at the DRACO PW laser

Rehwald, M.; Bernert, C.; Curry, C.; Cowan, T.; Gauthier, M.; Glenzer, S.; Goede, S.; Kim, J.; Kluge, T.; Kraft, S.; Obst-Hübl, L.; Schoenwaelder, C.; Schlenvoigt, H.-P.; Schramm, U.; Ziegler, T.; Zeil, K.

As high power laser systems producing high repetition rate pulses become interesting for applications in e.g.
radiation therapy, there is a high demand for rapid and controlled target delivery at the high power laser focus.
Due to their continuous and debris-free operation, cryogenic target systems producing renewable jets of
hydrogen [1] or other species proved to be very beneficial. Furthermore, the low plasma density of solid single
species hydrogen of only 30nc@800nm and the availability of different jet geometries allowed for gaining
deeper understanding of the laser proton acceleration process [2,3,4]. In this talk we focus on the
implementation of a hydrogen jet target at the Petawatt (PW) beam line of the high power laser source DRACO
at HZDR. The laser system delivers pulses with energies of up to 23J and pulse durations of about 30 fs on
target. We present significant improvements of the operation robustness of the cryogenic target with respect to
the harsh environment around the interaction zone and thereby leading to substantial increase in stability of the
laser accelerated proton beams. Prior and during experiments, characterization of the jet target was conducted
with a synchronized off-harmonic optical probe laser. It allowed for on-shot study of the onset of ionization
induced by the leading edge of the main laser pulse prior to its intensity maximum with sub-picosecond time
resolution. Also, by adding artificial pre-pulses the initial shape and size of the target can be engineered for
optimal interaction conditions with the high intensity laser pulse.

  • Lecture (Conference)
    4th Targetry for High Repetition Rate Laser-Driven Sources Workshop, 09.-12.06.2019, Milano, Italien

Permalink: https://www.hzdr.de/publications/Publ-30494
Publ.-Id: 30494


Nonperturbative signatures of nonlinear Compton scattering

Hernandez Acosta, U.; Otto, A.; Kämpfer, B.; Titov, A.

The probabilities of various elementary laser/photon/electron/positron interactions display in selected phase space and parameter regions typical nonperturbative dependencies such as proportional to P exp{/aE(crit)/E}, where P is a preexponential factor, E-crit denotes the critical Sauter/Schwinger field strength, and E characterizes the (laser) field strength. While the Schwinger process with a = a(S) pi and the nonlinear Breit/Wheeler process in the tunneling regime with a = a(nlBW) 4m/3 omega' (with omega' the probe photon energy and m the electron/positron mass) are famous results, we point out here that also the nonlinear Compton scattering exhibits a similar behavior when focusing on high harmonics. Using a suitable cutoff c > 0, the factor a becomes a = a(nlC) 2/3 cm/(p(0) + root p(0)(2) / m(2)). This opens the avenue toward a new signature of the boiling point of the vacuum even for field strengths E below E-crit by employing a high electron beam/energy p(0) to counter balance the large ratio E-crit/E by a small factor a to achieve E/a -> E-crit. In the weak/field regime, the cutoff facilitates a threshold leading to multiphoton signatures showing up in the total cross section at subthreshold energies.

Keywords: non-linear Compton scattering; strong-field QED; Breit-Wheeler pair production; Schwinger effect

Permalink: https://www.hzdr.de/publications/Publ-30493
Publ.-Id: 30493


Hybrid LWFA-PWFA staging; from concept to proof-of-principle experiments

Irman, A.; Bussmann, M.; Chang, Y.-Y.; Corde, S.; Couperus Cabadağ, J. P.; Debus, A.; Ding, H.; Döpp, A.; Heinemann, T.; Hidding, B.; Gilljohann, M. F.; Götzfried, J.; Karsch, S.; Kononenko, O.; Kurz, T.; Köhler, A.; Martinez De La Ossa, A.; Pausch, R.; Raj, G.; Schindler, S.; Schöbel, S.; Zarini, O.; Assmann, R. W.; Schramm, U.

Beam-driven plasma wakefield accelerators (PWFAs) offer a unique regime for the generation and acceleration of high-quality electron beams to multi-GeV energies. Here we present an innovative hybrid staging approach, deploying electron beams generated in a laser-driven wakefield accelerator(LWFA) as drivers for a PWFA, integrated in a particularly compact setup. This scenario exploits the capability of LWFAs to deliver shortest, high peak-current electron bunches [1] with the prospects for high-quality witness beam generation in PWFAs [2]. The feasibility of the concept is presented through exemplary particle-in-cell simulations, before describing experimental results from extensive campaigns performed at high-power laser facilities; ATLAS (LMU, Munich), SALLE-JAUNE (LOA, Paris) and DRACO (HZDR, Dresden). Using few-cycle optical probing we captured clear images of beam-driven plasma waves in a dedicated plasma stage, allowing us to identify a non-linear plasma-wave excitation regime. Trailing the plasma waves, the impact of ion motion to the transverse modulation of the plasma density was observed over many picoseconds [3]. Furthermore, we demonstrate for the first time the acceleration of distinct witness beams in such LWFA-driven PWFA (LPWFA) setup, showcasing an accelerating gradient on the order of 100 GV/m. These milestones pave the way towards compact sources of energetic ultra-high brightness electron beams as well as a miniature model for large scale PWFA facilities.

Keywords: laser wakefield acceleration; plasma wakefield acceleration

Related publications

  • Open Access Logo Lecture (Conference)
    European Advanced Accelerator Concept (EAAC), 20.09.2019, ELBA, Italia

Permalink: https://www.hzdr.de/publications/Publ-30492
Publ.-Id: 30492


Field driven recovery of the collective spin dynamics of the chiral soliton lattice

Trindade Goncalves, F. J.; Shimamoto, Y.; Sogo, T.; Paterson, G. W.; Kousaka, Y.; Togawa, Y.

We investigate the magnetic field dependence of the spin excitation spectra of the chiral soliton lattice (CSL) in the helimagnet CrNb₃S₆, by means of microwave resonance spectroscopy. The CSL is a prototype of a noncollinear spin system that forms periodically over a macroscopic length scale. Following the field initialisation of the CSL, we found three collective resonance modes over an exceptionally wide frequency range. With further reducing the magnetic field towards 0 T, the spectral weight of these collective modes was disrupted by the emergence of additional resonances whose Kittel-like field dependence was linked to coexisting field polarised magnetic domains. The collective behaviour at a macroscopic level was only recovered upon reaching the helical magnetic state at 0 T. The magnetic history of this non collinear spin system can be utilized to control microwave absorption, with potential use in magnon driven devices.

Related publications

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Permalink: https://www.hzdr.de/publications/Publ-30491
Publ.-Id: 30491


Enhanced ion heating with ~ keV temperature at solid density in high power laser-driven buried layer targets for NEEC/NEET

Huang, L.; Prencipe, I.; Laso García, A.; Cowan, T.

The coupling between high power laser-driven plasmas physics, atomic physics and nuclear physics aiming to detect and study NEEC/NNET is a very interesting and exciting research area. In this talk, we propose to study NEET/NEEC in buried layer targets, using high repetition-rate (1-10 Hz) 100 TW to PW class laser systems. In this scenario, extreme conditions of highly charged ions with ~ keV temperature at solid density are predicted by our Particle-In-Cell (PIC) simulations (including both collisions and ionization) enabling the study of NEET/NEEC in buried layers [1]. The simulations show that the expansion/compression waves are launched at layer interfaces due to Gigabar electron pressure gradients caused by return current heating. The hydro-motion pushed by the expansion/compression waves is rapidly converted into thermal motion mainly due to the efficient ion-ion collisional coupling, leading to the extreme temperatures at about solid density. The experimental feasibility to realize NEET/NEEC at the HZDR DRACO laser and the HiBEF laser at EuXFEL will be discussed [2].
[1] L. G. Huang, M. Bussmann, T. Kluge, A. L. Lei, W. Yu, and T. E. Cowan, Phys. Plasmas 20, 093109 (2013).
[2] http://www.hibef.eu.

Keywords: plasmas physics; atomic physics; nuclear physics; NEEC/NNET

  • Lecture (Conference)
    Time domain control of atomic shell for nuclear excitation, 07.-09.10.2019, Lerici, Italy

Permalink: https://www.hzdr.de/publications/Publ-30490
Publ.-Id: 30490


Laser-proton acceleration from a cryogenic hydrogen jet at the DRACO PW laser

Rehwald, M.; Bernert, C.; Curry, C.; Cowan, T.; Gauthier, M.; Glenzer, S.; Goede, S.; Kim, J.; Kluge, T.; Kraft, S.; Obst-Hübl, L.; Schoenwaelder, C.; Schlenvoigt, H.-P.; Schramm, U.; Ziegler, T.; Zeil, K.

Demanding applications like radiation therapy of cancer have pushed the development of laser proton accelerators and defined necessary proton beam properties as well as levels of control and stability.
The presentation will give an overview of the recent experiments for laser driven proton acceleration employing a cryogenic target system which is capable of producing a renewable and debris free jet target. The micrometer sized pure hydrogen jet is characterized by a low plasma density of 30 times the critical density at 800 nm and was irradiated at the Petawatt (PW) amplifier stage of the high power laser source DRACO at the HZDR. The Ti:sapphire system delivers laser pulses with energies of up to 23 J and pulse durations of 30 fs on target.
In this talk we present substantially improvements of the target system leading to an increase in stability of the accelerated protons as well as the long-term operations. Evaluation of different target geometries (cylindrical with a diameter of 5µm and planar with up to 4x20 µm²) demonstrating the capabilities in terms of size and shape of available hydrogen jets.
We report on the laser contrast dependencies of the proton beam properties by introducing artificial pre-pulses and describe their influence on the target shape at the interaction time by using a synchronized optical probe beam.
Furthermore different ion diagnostics reveal mono-species proton acceleration in the laser incidence plane from the jet target, reaching foil-like proton cut-off energies in target normal direction.

  • Lecture (Conference)
    Laser Plasma Accelerator Workshop 2019, 06.05.2019, Split, Kroatien

Permalink: https://www.hzdr.de/publications/Publ-30489
Publ.-Id: 30489


Using XFELs to Probe Extreme Magnetic Fields Inside Solid Targets Driven by Optical High Power Lasers at HiBEF

Huang, L.; Schlenvoigt, H.-P.; Takabe, H.; Cowan, T.

In this talk, we will firstly present a systematic study of the bulk magnetic field generation using particle-in-cell simulations, that we observe the effect of varying the laser and target parameters, including laser intensity, focal size, incident angle, preplasma scale length, target thickness and material, and experimental geometry. The simulation results suggest that the strongest magnetic field is generated with laser incident angles and preplasma scale lengths that maximize laser absorption efficiency. The simulations have also shown that the collisional ionization potential and model are critical to determining the structure and diffusion time of the self-generated magnetic fields. Then we will propose to probe the bulk magnetic fields inside the solid density plasmas by X-Ray polarimetry via Faraday rotation using an X-Ray free electron lasers (XFEL), taking its advantage of simultaneous high spatial-temporal resolution and several tens of micrometers attenuation length in solid. The synthetic simulations predict that the XFEL polarization is rotated by a few hundred micro-radians after penetrating through solid density plasmas which is feasible to be measured with X-Ray polarimetry.
With the results of this work, we are in an excellent position to maximize our chances of measuring laser generated magnetic fields using Faraday rotation at high power laser beamlines at XFELs. One of the first examples of this will be at the European XFEL-HED endstation, in the frame of Helmholtz International Beamline for Extreme Fields at the European XFEL (HiBEF) project, where a 7.5J/300TW high power laser has already installed as a permanent instrument. A dedicated beamtime at the European XFEL-HED endstation to investigate the performance of ultra-high purity X-ray polarimeters under the conditions of European XFEL source has already been scheduled in the end of May, 2019. This is expected to become the basis to probe the laser-driven ultra-strong magnetic fields inside the solid-density targets, accessed via plasma Faraday rotation and imaging polarimetry.

Keywords: magnetic field; X-Ray polarimetry; Faraday rotation; XFEL

  • Invited lecture (Conferences)
    The 4th International Conference on Matter and Radiation at Extremes (ICMRE 2019), 29.05.-02.06.2019, Hefei, China

Permalink: https://www.hzdr.de/publications/Publ-30488
Publ.-Id: 30488


Minimization of resource use via flowsheet optimization: The case of Aluminum recycling

Hannula, J. O.; Bartie, N. J.; Luukkanen, S.; Reuter, M.

The integrated flow of primary and secondary resources in the loop is in the centre of the Circular Economy (CE) paradigm. To optimize the use of resources, a system-wide thinking, which links the primary and secondary production of the whole processing chain, is required. Digitalization and process simulation enable the linking of these relevant aspects together, optimising the resource use and minimising the environmental impact.

Aluminium’s reactivity poses a challenge for resource efficient recycling. In the re-melting of Al scrap, most of the impurities remain in the molten aluminium. This emphasizes the importance of the quality of the scrap in preventing contamination and reducing the need for dilution with primary aluminium in the alloying phase.

This paper analyses an aluminium recycling flowsheet that combines detailed physical separation models with re-melting and alloy production. The simulation model captures the impact feed quality and the efficiency of the physical separation stage have on specific alloy production. Optimum strategies for alloy production can be found for each specific feed type to minimise resource consumption. The paper demonstrates how digitalization allows more precise and efficient use of finite resources in the sense of CE.

Keywords: Circular Economy; Aluminum recycling; Simulation; Optimization

  • Contribution to proceedings
    XXX International Mineral Processing Congress (IMPC 2020), 18.-23.10.2020, Cape Town International Convention Centre (CTICC), South Africa
    Proceedings of the IMPC 2020

Permalink: https://www.hzdr.de/publications/Publ-30487
Publ.-Id: 30487


Mutual dependence of oxygen and vacancy diffusion in bcc Fe and dilute iron alloys

Wang, X.; Faßbender, J.; Posselt, M.

A combination of density functional theory (DFT) and an efficient calculation method based on Atomistic Kinetic Monte Carlo simulations (AKMC) is used to investigate the interdependence of oxygen (O) and vacancy (v) diffusion in bcc Fe and in dilute iron alloys with the substitutional atoms Y and Ti. Both O and v are considered as mobile while the substitutional atoms are assumed to be immobile. DFT is applied to determine the binding energy between O and v for different distances, the migration barriers for O in the environment of v, and the corresponding barriers of v in the vicinity of O. In agreement with previous work O and v have a very strong binding at the 1st neighbor distance. On the other hand, the calculations show that the Ov pair at the 6th neighbor distance is instable. The newly found simultaneous jumps of both O and v compensate the lack of jump paths that would occur due to this instability. The DFT results are employed to determine the diffusion coefficient of O and v using the AKMC-based calculation method. At first a model system with fixed O and v concentrations is studied. It is found that even a small v content of some ppm can lead to a strong reduction of the O diffusivity. A similar effect is obtained for v diffusion under the influence of O. Furthermore, investigations on the interdependence of O and v diffusion in the first phase of thermal processing of oxide dispersion strengthened iron alloys are performed, and the influence of the substitutional atoms Y and Ti is studied. A simple thermodynamic model is employed to determine the concentration of O, Y, and Ti monomers as well as the total v concentration, for a typical total content of O, Y, and Ti. These results are used in calculations of the diffusion coefficients of O and v. Not only a strong mutual dependence but also a significant influence of Y on O diffusion is found. Finally, O and v diffusivities in a system with an O content close to the thermal solubility are calculated, where the monomer and total concentrations are determined by two different thermodynamic models. Even for such a low amount of O in the alloy the diffusion coefficients differ strongly from those in perfect bcc Fe.

Keywords: Ferritic iron alloys; Mutual dependence of oxygen and vacancy diffusion; First-principle calculations; Atomistic Kinetic Monte Carlo simulations; Influence of substitutional atoms

Permalink: https://www.hzdr.de/publications/Publ-30485
Publ.-Id: 30485


Scaling up the Synthesis of a Hydroxyquinoline-Functionalized p‑tert-Butylcalix[4]arene.

Roode-Gutzmer, Q. I.; Holderied, L. N.; Glasneck, F.; Kersting, B.; Fröhlich, P.; Bertau, M.

The optimization for an upscaled technical production of a lower rim-functionalized p-tert-butylcalix[4]arene, furnished with N₄O₄-donor ligands for superior solvent extraction separation between heavy and light lanthanides, is described. We demonstrate that reducing the polarity of the aprotic solvent in the (1,3)-distal esterification of p-tert-butylcalix[4]arene 1 does not compromise the quality or yield of product 2. It was possible to use the technical quality educt 1, that is, without prior crystallization in toluene, in conjunction with reductions in reaction time and solvent volume. The raw diester product 2 could be used, without prior recrystallization (which originally required 3 days) in the condensation reaction with hydrazine monohydrate to form hydrazide 3. Most importantly, the solvent volume required in the final condensation reaction of 3 with 8- hydroxyquinoline-2-carboxaldehyde could be reduced by an order of magnitude by using chloroform. Not only was the final disubstituted product yield improved but also the purity of the final product could be ensured by preventing the precipitation of the intermediate monosubstituted product during reaction. The filtration characteristics of the final product, as well as its solvation properties during solvent extraction of lanthanides were significantly improved.

Keywords: rare earths; lanthanides; actinides; solvent extraction; calixarene synthesis; scale up

Permalink: https://www.hzdr.de/publications/Publ-30484
Publ.-Id: 30484


Characterization of Goethe’s prisms by external ion beam

Munnik, F.; Mäder, M.; Heller, R.; Schreiber, A.; Müller, O.

Johann Wolfgang von Goethe is known the world over as a renowned writer. However, he was also involved in scientific studies and has written several scientific books, of which he considered the “Theory of colours” (“Farbenlehre”, 1400 pages published in 1810) his most important work overall. In this work, he characterises colours as arising from the interplay between light and dark. This is in contrast to Newton’s analytical treatment of colour from one century earlier, which is based on the observation that white light can be separated into colours with a prism, that Goethe opposed. Over the centuries, Goethe’s theory was discredited and Newton’s theory prevailed. However, Goethe performed systematic and accurate optical measurements.
For these experiments, he and his partner J. Ritter, who discovered UV-light, used water prisms and glass prisms ordered from a glassmaker in Jena. The aim of current research is to reconstruct these optical experiments and the observed spectra [1]. For this, detailed knowledge of the composition of the glass prisms is important. This knowledge is, for example, also important to evaluate how innovative his prisms were.
Therefore, eleven prisms from Goethe’s estate or from contemporary sources belonging to the Klassik Stiftung Weimar have been analysed at the external beam setup of the Ion Beam Center at the HZDR. A 4 MeV proton beam has been used to acquire PIXE, PIGE and RBS spectra, sometimes on several areas. Care had to be taken to minimise damage by using short measurement times and measuring on inconspicuous areas because the glass quickly showed dark spots under irradiation. The PIXE and PIGE spectra have been used for quantitative analysis in an iterative procedure and the RBS spectra have only been evaluated quantitatively. The results of this analysis and the interpretation are presented in this work.

Related publications

  • Lecture (Conference)
    16th International Conference on Particle Induced X-ray Emission, 24.-29.03.2019, Caldas da Rainha, Portugal

Permalink: https://www.hzdr.de/publications/Publ-30483
Publ.-Id: 30483


Junctionless Nanowire Transistors: an Excellent Platform for Ultrasensitive Chemo/Biosensors

Georgiev, Y.

Junctionless nanowire transistors (JNTs) are gated resistors where the source, channel and drain have the same type of doping without any dopant concentration gradient. The JNT is the simplest transistor structure possible and probably the most scalable of all field effect transistor (FET) structures. It is easier to fabricate than standard metal-oxide-semiconductor FETs (MOSFETs) and has also a number of performance advantages over them. [1, 2, 3] Two of the advantages are especially important for the JNT application as sensors:

1. The current flow in JNTs is not controlled by a reverse biased p-n junction as in standard MOSFETs but entirely by the gate potential. Therefore, they are more sensitive to any change in the electrostatic potential on the channel surface acting as a gate potential.

2. JNTs demonstrate bulk conductance near the centre of the channel, in contrast to the conductance in a thin surface inversion or accumulation layer near the gate in the inversion mode or accumulation mode MOSFETs, which leads to higher drive currents. Moreover, this fact makes the conduction in JNTs less affected by the noise-inducing parasitic surface states than in the case of conventional MOSFETs, which is very important for achieving high signal-to-noise ratio and low detection limit.

In the presentation, these advantages will be discussed in detail followed by results of implementation of silicon (Si) JNTs as chemical and biological sensors. A series of experiments for sensing the ionic strength and the pH value of buffer solutions have proven the excellent sensitivity of these sensors. [4, 5] Moreover, sensing of the protein streptavidin at a concentration as low as 580 zM has been observed, which is by far the lowest concentration of this protein ever detected and corresponds to detection in the range of only few molecules.

The high sensitivity of JNT sensors, combined with their very simple structure and relaxed fabrication process, makes them promising candidates for cheap mass production by the conventional microelectronic technology. This can enable their numerous applications in various fields where fast, low-cost, label-free, low-volume and real-time detection of chemical and biological species at low detection levels is required.

REFERENCES:

[1]. J.P. Colinge, C.-W. Lee, A. Afzalian, N. D. Akhavan, R. Yan, I. Ferain, P. Razavi, B. O'Neill, A. Blake, M. White, A.-M. Kelleher, B. McCarthy, R. Murphy. Nanowire transistors without junctions. Nature Nanotech. 5, 225 (2010).
[2]. J. P. Colinge, C. W. Lee, N. D. Akhavan, R. Yan, I. Ferain, P. Razavi, A. Kranti, R. Yu. Junctionless Transistors: Physics and Properties, in Semiconductor-On-Insulator Materials for Nanoelectronics Applications. (Eds: A. Nazarov, J. P. Colinge, F. Balestra, J.-P. Raskin, F. Gamiz, V. S. Lysenko), Springer-Verlag Berlin, Heidelberg, Germany, pp.187-200, Ch. 10 (2011).
[3]. J. P. Colinge, A. Kranti, R. Yan, C. W. Lee, I. Ferain, R. Yu, N. D. Akhavan, P. Razavi. Junctionless Nanowire Transistor (JNT): Properties and design guidelines. Solid State Electron. 65-66, 33 (2011).
[4]. Y.M. Georgiev, N. Petkov, B. McCarthy, R. Yu, V. Djara, D. O'Connell, O. Lotty, A. M. Nightingale, N. Thamsumet, J. C. deMello, A. Blake, S. Das, J. D. Holmes. Fully CMOS-compatible top-down fabrication of sub-50 nm silicon nanowire sensing devices. Microelectron. Eng. 118, 47 (2014).
[5]. Y. M. Georgiev, R. Yu, N. Petkov, O. Lotty, A. M. Nightingale, J. C. deMello, R. Duffy, J. D. Holmes. Silicon and Germanium Junctionless Nanowire Transistors for Sensing and Digital Electronics Applications, In "Functional Nanomaterials and Devices for Electronics, Sensors and Energy Harvesting", (Eds: A. Nazarov, F. Balestra, V. Kilchytska, D. Flandre), Springer International Publishing AG, Cham, Switzerland, pp. 367-388, Ch. 17 (2014).

Keywords: nanowires; biosensors; junctionless transistors; protein; streptavidin; single-molecule detection

  • Invited lecture (Conferences)
    IHRS NanoNet International Conference, 08.-11.10.2019, Dresden, Germany

Permalink: https://www.hzdr.de/publications/Publ-30482
Publ.-Id: 30482


Application of junctionless nanowire transistors as ultrasensitive biosensors

Georgiev, Y.; Petkov, N.; Yu, R.; Nightingale, A. M.; Buitrago, E.; Lotty, O.; Demello, J. C.; Ionescu, A. M.; Holmes, J. D.

Junctionless nanowire transistors (JNTs) have been recently proposed as a disruptive alternative of the conventional metal-oxide-semiconductor field-effect transistors (MOSFETs) [1]. They are gated resistors where the source, channel and drain have the same type of doping without any junctions and dopant concentration gradient. Thus JNT is the simplest possible transistor structure and probably the most scalable of all FET structures. It is easier to fabricate than standard MOSFETs and has also a number of performance advantages over them [1,2]. Therefore, JNTs have quickly attracted a vast interest. However, their application as sensors, although very appealing, has not yet been extensively studied.

Here we report on the fabrication of silicon JNTs and their implementation as chemical and biological sensors. The devices have been fabricated by a top-down approach mainly based on electron beam lithography and reactive ion etching (see Fig 1) [3]. The nanowire surfaces have been appropriately functionalised for the respective analytes of interest. A series of experiments (see Fig. 2) for sensing the ionic strength (see Fig. 3) and the pH value of buffer solutions have proven the excellent sensitivity of the fabricated sensors [3,4]. Moreover, sensing of the protein streptavidin at a concentration as low as 580 zM has been observed (see Fig. 4), which is by far the lowest concentration of this protein ever detected and corresponds to detection in the range of only few molecules.

To explain the ultrahigh sensitivity of JNT sensors, we will discuss in detail two advantages of JNTs over the classical MOSFETs [1-4], which are especially important for their application as sensors:

1. The current flow in JNTs is not controlled by a reverse biased p-n junction as in standard MOSFETs but entirely by the gate potential modulating the carrier density in the channel. Thus they are more sensitive to any change in the electrostatic potential on the channel surface acting as a gate potential.

2. JNTs demonstrate bulk conductance near the centre of the channel, in contrast to the conductance in a thin surface inversion or accumulation layer near the gate in the classical inversion mode or accumulation mode transistors, which leads to higher drive currents. Moreover, this fact makes the modulation of depletion and the conduction in JNTs less affected by the noise-inducing parasitic surface states than in the case of conventional MOSFETs, which is very important for achieving high signal-to-noise ratio and hence low detection limit [6,7].

The ultrahigh sensitivity of JNT sensors, combined with their very simple structure and relaxed fabrication process, makes them promising candidates for cheap mass production by the conventional microelectronic technology. This can enable their numerous applications in various fields where fast, low-cost, label-free, low-volume and real-time detection of chemical and biological species at low detection levels is required.

[1] J.P. Colinge, C.-W. Lee, A. Afzalian, N. D. Akhavan, R. Yan, I. Ferain, P. Razavi, B. O'Neill, A. Blake, M. White, A.-M. Kelleher, B. McCarthy, R. Murphy. Nature Nanotech. 5 (2010) 225-229.
[2] J. P. Colinge, A. Kranti, R. Yan, C. W. Lee, I. Ferain, R. Yu, N. D. Akhavan, P. Razavi. Solid State Electron. 65-66 (2011) 33-37.
[3] Y.M. Georgiev, N. Petkov, B. McCarthy, R. Yu, V. Djara, D. O'Connell, O. Lotty, A. M. Nightingale, N. Thamsumet, J. C. deMello, A. Blake, S. Das, J. D. Holmes. Microelectron. Eng. 118 (2014) 47-53.
[4] Y. M. Georgiev, R. Yu, N. Petkov, O. Lotty, A. M. Nightingale, J. C. deMello, R. Duffy, J. D. Holmes. Silicon and Germanium Junctionless Nanowire Transistors for Sensing and Digital Electronics Applications, in A. Nazarov, F. Balestra, V. Kilchytska, D. Flandre, eds., Functional Nanomaterials and Devices for Electronics, Sensors and Energy Harvesting, (Springer International Publishing AG, Cham, Switzerland, Ch. 17, 2014) 367-388.
[5] Y. M. Georgiev, N. Petkov, R. Yu, A. M. Nightingale, E. Buitrago, O. Lotty, J. De Mello, A. M. Ionescu, J. D. Holmes, Nanotechnology (2019), accepted, https://doi.org/10.1088/1361-6528/ab192c
[6] N. K. Rajan, D. Routenberg, M. Reed. Appl. Phys. Lett. 98 (2011) 264107.
[7] K. Bedner, V. A. Guzenko, A. Tarasov, M. Wipf, R. L. Stoop, S. Rigante, J. Brunner, W. Fu, C. David, M. Calame, J. Gobrecht, C. Schönenberger. Sensor. Actuat. B-Chem. 191 (2014) 270.

Keywords: nanowires; biosensors; junctionless transistors; protein; streptavidin; single-molecule detection

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  • Lecture (Conference)
    45th International Conference on Micro- and Nanofabrication and Manufacturing (MNE 2019), 23.-26.09.2019, Rhodes, Greece

Permalink: https://www.hzdr.de/publications/Publ-30481
Publ.-Id: 30481


Multi-direction channelling study of the Ag:YSZ nanocomposites prepared by ion implantation

Mikšová, R.; Jagerová, A.; Malinský, P.; Harcuba, P.; Veselý, J.; Holý, V.; Kentsch, U.; Macková, A.

The paper reports on implantation damage accumulation, Ag distribution and the interior morphology in different crystallographic orientations of implanted samples of cubic yttria-stabilised zirconia (YSZ). (100)-, (110)- and (111)-oriented YSZ was implanted with 400-keV Ag⁺ ions at ion fluences from 5 × 10¹⁴ to 5 × 10¹⁶ cm⁻². Rutherford backscattering spectrometry (RBS) in the channelling mode (RBS-C), as well as X-ray diffraction (XRD), were used for the quantitative measurement of the lattice disorder and Ag distribution. The defect propagation and Ag accumulation were observed using transmission electron microscopy (TEM) with the energy-dispersive X-ray spectroscopy (EDX). Although similar damage evolution trends were observed along with all channelling directions, the disorder accumulation is lower along the <110> direction than along the <100> and <111> direction. The damage extends much deeper than the theoretically predicted depths. It is attributed to long-range defect migration effects, confirmed by TEM. At the ion fluence of 5 × 10¹⁶ cm⁻², nanometre-sized Ag precipitates were identified in the depth of 30–130 nm based on the Ag concentration–depth profiles determined by RBS.

Keywords: Ag ion-implantation; Yttria-stabilized zirconia; Damage accumulation; Strain relaxation; Nanoparticles

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Permalink: https://www.hzdr.de/publications/Publ-30480
Publ.-Id: 30480


Group IV Nanowires: Fabrication and Particular Applications

Georgiev, Y.; Khan, M. B.; Deb, D.; Echresh, A.; Ghamsari, S. J.; Prucnal, S.; Rebohle, L.; Erbe, A.; Helm, M.; Gangnaik, A. S.; Game, A. D.; Biswas, S.; Petkov, N.; Holmes, J. D.

Group IV semiconductor nanowires (NWs) are very attractive because of the variety of possible applications as well as of the good silicon (Si) compatibility, which is important for their integration into the existing semiconductor technology.

We will give an overview of our activities on fabrication and application of group IV NWs. These include top-down fabrication (based on electron beam lithography and reactive ion etching) of Si and germanium (Ge) NWs having widths down to 6-7 nm as well as bottom-up (vapour-liquid-solid, VLS) growth of alloyed germanium-tin (Ge1-xSnx) NWs with x = 0.07-0.1 and diameters of 50-70 nm. We will also discuss the innovative nanoelectronic devices that we are working on: junctionless nanowire transistors (JNTs) and reconfigurable field effect transistors (RFETs). In particular, we will present results on Si JNTs for sensing application as well as on Ge and GeSn JNTs for digital logic. We will also show results on Si RFETs as well as preliminary data on SiGe and GeSn RFETs, which are expected to outperform the Si RFETs.

Keywords: semiconductor nanowires; top-down nanofabrication; electron beam lithography; reactive ion etching; bottom-up nanofabrication; nanoelectronic devices; junctionless nanowire transistors; reconfigurable field effect transistors; biosensors

Related publications

  • Lecture (Conference)
    83d DPG Annual Conference and DPG Spring Conference, 31.03.-05.04.2019, Regensburg, Germany

Permalink: https://www.hzdr.de/publications/Publ-30479
Publ.-Id: 30479


Fabrication and Particular Applications of Group IV Semiconductor Nanowires

Georgiev, Y.; Khan, M. B.; Deb, D.; Echresh, A.; Jazavandi Ghamsari, S.; Prucnal, S.; Rebohle, L.; Erbe, A.; Helm, M.; Gangnaik, A. S.; Game, A. D.; Biswas, S.; Petkov, N.; Holmes, J. D.; Knoch, J.

During the last 1-2 decades semiconductor nanowires (NWs) have received significant academic and commercial attention due to their attractive electrical and mechanical properties and large surface area to volume ratios. They have a variety of possible applications including nanoelectronics, nanophotonics, photovoltaics, sensorics, etc. Among all semiconductor NWs the ones based on group IV materials have the advantage of being the most silicon (Si) compatible. This is very important since their integration into the existing semiconductor technology platform can be relatively easy.

We will give a general overview of our activities on group IV nanowires. We will first present the NWs that we are working with, including top-down fabricated Si and germanium (Ge) NWs having widths down to 6-7 nm as well as bottom-up grown alloyed germanium-tin (Ge1-xSnx) NWs with x = 0.07-0.1, diameters of 50-70 nm and lengths of 1 to 3 µm. We are currently working also on the fabrication of alloyed SiGe and SiGeSn NWs with varying content of the different materials.

Next, we will discuss the innovative nanoelectronic devices that we are working on, namely junctionless nanowire transistors (JNTs) and reconfigurable field effect transistors (RFETs). In particular, we are fabricating Si JNTs for sensing application as well as Ge and GeSn JNTs for digital logic. Concerning RFETs, we are currently working on Si RFETs and commencing activities on SiGe and GeSn RFETs, which are expected to outperform the Si RFETs.

Finally, we will briefly present a novel device concept that we recently invented: a specific group IV heterostructure band-to-band tunnel FET (TFET). The fabrication process of this device is scalable and fully CMOS compatible and should allow the achievement of high on-current Ion together with low off-current Ioff, hence steep subthreshold slope.

Keywords: semiconductor nanowires; top-down nanofabrication; bottom-up nanofabrication; nanoelectronic devices; junctionless nanowire transistors; reconfigurable field effect transistors; band-to-band tunnel field effect transistors; biosensors

Related publications

  • Lecture (Conference)
    The 10th workshop “Towards Reality in Nanoscale Materials X”, 12.-14.02.2019, Levi, Finland

Permalink: https://www.hzdr.de/publications/Publ-30478
Publ.-Id: 30478


Vanishing influence of the band gap on charge exchange of slow highly charged ions in freestanding single layer MoS₂

Creutzburg, S.; Schwestka, J.; Niggas, A.; Inani, H.; Tripathi, M.; George, A.; Heller, R.; Kozubek, R.; Madauß, L.; Facsko, S.; Kotakoski, J.; Schleberger, M.; Turchanin, A.; Grande, P. L.; Aumayr, F.; Wilhelm, R. A.

Charge exchange and kinetic energy loss of slow highly charged xenon ions transmitted through freestanding monolayer MoS₂ are studied. Two distinct exit charge state distributions, characterized by low and high charge exchange, are observed. They are accompanied by smaller and larger kinetic energy losses, respectively. High charge exchange is attributed to two-center neutralization processes, which take place in close impact collisions with the target atoms. Experimental findings are compared to graphene as a target material and simulations based on a time-dependent scattering potential model. Independently of the target material, experimentally observed charge exchange can be modeled by the same electron capture and de-excitation rates for MoS₂ and graphene. A common dependence of the kinetic energy loss on the charge exchange for MoS₂ as well as graphene is also observed, which additionally underlines the common nature of the two-center Auger neutralization process. Considering the similarities of the zero band gap material graphene and the 1.9 eV direct band gap material MoS₂, we suggest that electron transport on the femtosecond time scale is dominated by the strong influence of the ion’s Coulomb potential in contrast to the dispersion
defined by the material’s band structure.

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Permalink: https://www.hzdr.de/publications/Publ-30477
Publ.-Id: 30477


Adaptive Control of Meniscus Velocity in Continuous Caster Based on NARX Neural Network Model

Abouelazayem, S.; Glavinic, I.; Wondrak, T.; Hlava, J.

Meniscus velocity in continuous casting process is critical in determining the quality of the steel. Due to the complex nature of the various interacting phenomena in the process, designing model-based controllers can prove to be a challenge. In this paper a NARX neural network model is trained to describe the complex relationship between the applied magnetic field from an Electromagnetic Brake (EMBr) and the meniscus velocity. The data for the model is obtained using a laboratory scale continuous casting plant. The next step was to use Adaptive Model Predictive Control (MPC) to deal with the non-linearity of the model by adapting the prediction model to the different operating conditions. The controller will utilize the EMBr as an actuator to keep the meniscus velocity within the optimum range, and reject disturbances that occur during the casting process such as changing the casting speed.

Keywords: Mining; mineral and metal; Nonlinear system identification; Adaptive control design

Permalink: https://www.hzdr.de/publications/Publ-30476
Publ.-Id: 30476


Control of Jet Flow Angle in Continuous Casting Process using an Electromagnetic Brake

Abouelazayem, S.; Glavinic, I.; Wondrak, T.; Hlava, J.

The flow pattern in the mould of the continuous casting is an important factor in determining the quality of the steel slabs that are produced in the end of the process. Hence it can heavily influence manufacturing costs due to the scrap percentage. Electromagnetic actuators are frequently used in the continuous casting process to stabilize the flow in the mould and therefore produce higher quality of steel slabs. Usually they are used in open loop but their effect on the flow pattern may be much better directed if they are used as a part of closed loop control based on real time measurements. In this paper, a closed loop controller is proposed that adjusts the magnetic field of an electromagnetic brake using the real time measurement of the angle of the jet flowing from the Submerged Entry Nozzle (SEN). The angle is kept within a specific range by the controller in order to prevent a deeper jet impingement into the mould; this allows us to achieve the desirable double roll flow pattern, and to avoid the entrapment of slugs. The controller is based on a model of the relationship between brake current and jet angle that was obtained using experimental data from a laboratory scale continuous casting plant.

Keywords: Flow Control; Tomography; Process Automation; Model Predictive Control

  • Contribution to proceedings
    Mining, Mineral and Metal Processing 2019, 28.-30.08.2019, Stellenbosch, South Africa
    Control of Jet Flow Angle in Continuous Casting Process using an Electromagnetic Brake
    DOI: 10.1016/j.ifacol.2019.09.169
    Cited 5 times in Scopus

Permalink: https://www.hzdr.de/publications/Publ-30475
Publ.-Id: 30475


Switched MPC Based on Clogging Detection in Continuous Casting Process

Abouelazayem, S.; Glavinic, I.; Wondrak, T.; Hlava, J.

Nozzle clogging contributes heavily to quality issues seen during the process of continuous casting. The presence of clogging in the Submerged Entry Nozzle (SEN) can significantly change the flow patterns in the mould and therefore impact the quality of the steel product. Also, there is a high risk of inclusions due to parts of the clogging material breaking off and entering the mould. In this paper, we propose a new sensor setup that allows us to detect clogging in the SEN by monitoring the angle of the exiting jet. Based on this clog detection setup, a switched MPC controller is used to keep the angle of the exiting jet between the optimum ranges using an Electromagnetic Brake. This allows the controller to keep the angle of the jet in the optimum range even when clogging occurs in the nozzle. Experimental data from a laboratory scale continuous caster is used to derive the models for the controller.

Keywords: Flow Control; Tomography; Switched MPC; Hammerstein-Wiener Model

  • Contribution to proceedings
    IFAC 2020 World Congress, 12.-17.07.2020, Berlin, Germany
    Switched MPC Based on Clogging Detection in Continuous Casting Process

Permalink: https://www.hzdr.de/publications/Publ-30474
Publ.-Id: 30474


Two new diffractometers at BM20/ESRF for single crystal, powder and surface diffraction

Hennig, C.; Schmidt, M.; Ikeda-Ohno, A.; Radoske, T.; Feig, M.; Findeisen, S.; Claußner, J.; Exner, J.; Naudet, D.; Baumann, N.; Scheinost, A.

The Institute of Resource Ecology / Helmholtz-Zentrum Dresden-Rossendorf is operating the Rossendorf Beamline (ROBL/BM20) at the European Synchrotron Radiation Facility (ESRF) for 20 years. We are constructing a second experimental hutch with two new diffractometers for single crystal, powder and surface diffraction. The single crystal diffractometer is foreseen for small and large molecule crystallography, mainly for structures with heavy metals. This diffractometer is equipped with a Pilatus3 X 2M detector mounted in a sturdy metal frame on a granite table. Sample-detector distances can be varied between 140 und 600mm. Three goniometers are available to mount single crystals: a Huber Kappa goniometer 512.410, an Arinax Kappa MK3, and a Huber uniaxial goniometer 410. The energy range of 5-35keV allows the application of anomalous dispersion. In-situ experiments on single crystals and powders are supported. Diffraction measurements can be combined simultaneously with XANES and XRF spectroscopy using a Vortex X90 CUBE silicon drift detector with a FalconX1 processor.
The second diffractometer will be used for surface diffraction and moderate high-resolution powder diffraction. This diffractometer is a 6-circle Huber diffractometer with Eulerian cradle geometry. Surface and powder diffraction techniques comprise specific setups. Both techniques will use a Pilatus 100k detector. The resolution for powder diffraction using the Pilatus 100k detector does not reach the resolution of synchrotron diffractometers with secondary analyzer crystals, but provides a magnitude better resolution than lab diffractometers. A specific support allows the installation of the Vortex X90 detector also on this diffractometer. The setup comprises a cryo cooler (80-400 K) and a heater (up to 1200 K) which can be installed at both diffractometers. The experimental hutch is equipped for the use of radioactive material.

Keywords: Single crystall diffraction; powder diffraction; surface diffraction; Rossendorf Beamline

Related publications

  • Lecture (Conference)
    Joint Polish-German Crystallographic Meeting 2020, 24.-27.02.2020, Wroclaw, Poland

Permalink: https://www.hzdr.de/publications/Publ-30473
Publ.-Id: 30473


Flow monitoring for continuous steel casting using Contactless Inductive Flow Tomography (CIFT)

Glavinic, I.; Ratajczak, M.; Stefani, F.; Wondrak, T.

The control of the liquid steel flow in the mould of a continuous caster based on real time flow measurements is a challenging task due to the lack of appropriate measurement techniques. The opaqueness, the high temperature of 1500 C and the chemical aggressiveness of the melt require non-optical contactless methods. In order to reconstruct the complex flow structure in the mould, the Contactless Inductive Flow Tomography (CIFT) is a promising candidate, since it allows the visualization of the flow structure in the melt by applying a magnetic field to the melt, measuring the flow induced perturbation of that field and solving subsequently a linear inverse problem. The combination of this new measurement technique with typical electromagnetic actuators like electromagnetic brakes used in continuous casting, pose a challenge to the CIFT measurement system, because the flow induced magnetic field is in the range of 100 nT and has to be measured robustly on the background of the static magnetic field with the amplitude of 300 mT generated by the brake. In this work we will show recent developments regarding this topic for a small model of a continuous caster in the lab.
Furthermore, we will present a new method on how the complex linear inverse problem can be solved in real time providing a time resolution of about 1 Hz.

Keywords: Tomography-based industrial process control; CIFT; Continuous casting; mini-LIMMCAST; Process tomography sensors

  • Contribution to proceedings
    IFAC 2020 World Congres, 12.-17.07.2020, Berlin, Deutschland
    Proceedings of the IFAC 2020 World Congres

Permalink: https://www.hzdr.de/publications/Publ-30472
Publ.-Id: 30472


Experimental study on the magnetic pulse welding process of large aluminum tubes on steel rods

Bellmann, J.; Schettler, S.; Dittrich, S.; Lueg-Althoff, J.; Schulze, S.; Hahn, M.; Beyer, E.; Tekkaya, A. E.

Solid state welding technologies enable dissimilar metal welding without critical intermetallic phase formation. Magnetic Pulse Welding (MPW) is a promising joining method for hybrid sheet connections in car body production or for manufacturing of dissimilar tube connections. Given a suitable MPW process design, the shear testing of MPW joints usually leads to failure in the weaker base material. This finding emphasizes the high strength level of the joining zone itself. Consequently, the transmission of higher forces or torques, respectively, requires stronger materials or adapted geometries. In the present experimental study, the diameter of an exemplary driveshaft was doubled to 80 mm at constant tube wall thickness to increase the load bearing capability. The characteristic impact flash was recorded at different positions around the tube’s circumference and it was used to adjust the most relevant process parameters, i.e. working length and acceleration gap, at the lower process boundary. In metallographic analysis, the final shapes of both joining partners were compared with the original driveshaft dummies on macroscopic and microscopic scale. The typical wavy interface between aluminum and steel was analyzed in detail. Doubling the tube diameter lead to four times higher torque levels of failure during quasistatic and cyclic torsion tests.

Permalink: https://www.hzdr.de/publications/Publ-30471
Publ.-Id: 30471


Near free-fall oscillatory velocities in liquid metal rotating convection

Vogt, T.; Horn, S.; Aurnou, J.

The geomagnetic field is induced by liquid metal ow inside Earths outer core as a self-excited dynamo. Buoyancy drives the liquid metal flow because the iron rich core is cooling from its primordial state through heat loss to the mantle. The rotation of the Earth and Lorentz forces alter the resulting convective flow. However, since a 3000 km thick rocky mantle hinders our ability to observe core dynamics, the detailed ow topology is still largely unknown. Here we will investigate the effect of rotation on a low Prandtl number thermal convection by means of laboratory experiments and DNS. Therefore, we consider a rotating Rayleigh-Bénard convection setup in an upright cylindrical vessel of aspect ratio Γ = D/H = 2. We investigate supercriticalities in the range of 1 < R < 20 and Ekman numbers 4x10^-4 < Ek < 5 x 10^-6 in liquid gallium at Pr = 0.03. We find that oscillatory convection generates velocity that appear to exceed predictions in steady convection. Multi-modal bulk oscillations dominate the vertical velocity field over the whole range of supercriticalities investigated. Additionally, coherent mean zonal flows and time-mean helicity is found in the rotating liquid metal convection. Thus, we show that these oscillatory flows can be relevant for dynamo action.

Keywords: Rotating convection; liquid metal; Rayleigh-Bénard convection

  • Lecture (Conference)
    72nd Annual Meeting of the American Physical Society’s Division of Fluid Dynamics (DFD), 23.-27.11.2019, Seattle, USA

Permalink: https://www.hzdr.de/publications/Publ-30469
Publ.-Id: 30469


Verminderung des Tumorwachstums durch Kombination von Radiotherapie, Decitabin und Abacavir in einem orthotopischen Gruppe-3-MB-Mausmodell

Gringmuth, M.; Patties, I.; Toussaint, M.; Kranz, M.; Böhme, L.; Kortmann, R.-D.; Glasow, A.

Fragestellung:

Medulloblastome (MBs) sind die häufigsten malignen Hirntumore im Kindesalter. Die derzeitige Therapie besteht aus Tumorresektion und Radio-Chemotherapie. Dennoch zeigen insbesondere Patienten mit SHH/p53-mutierten- sowie Gruppe-3-MBs eine schlechte Prognose mit einer 5-Jahres-Überlebensrate von nur 41 % sowie 45 %. Verbesserte Therapiestrategien stehen daher im Fokus der aktuellen Forschung.
Unser Projekt kombiniert Radiotherapie (RT) mit dem DNA-de-novo-Methyltransferase-Inhibitor Decitabin (5 Aza 2’-desoxycytidin) und dem Telomerase-Inhibitor Abacavir in einem orthotopischen MB Mausmodell, da in 70 % der primären MBs eine aberrante Hypermethylierung beziehungsweise erhöhte Telomeraseaktivitäten nachgewiesen wurden. Zudem konnten wir in vitro bereits zeigen, dass die Kombinationsbehandlung mit RT, Decitabin und Abacavir das klonogene Überleben signifikant verringert.
Methodik:
Alle Tierexperimente wurden durch die Landesdirektion Sachsen genehmigt (Reg.-Nr: TVV 30/14). NSG-Mäusen wurden Gruppe-3-MB-PDX-Zellen (DKFZ Heidelberg, Dr. Kool) stereotaktisch ins Cerebellum injiziert. Drei Wochen postoperativ wurde den Tieren täglich über 14 Tage Decitabin (0,1 mg/kg/Tag) und/oder Abacavir (50 mg/kg/Tag) intraperitoneal verabreicht. Die lokale Einzeit-Bestrahlung (2 Gy) erfolgte am Tag 8. Mit Erreichen der definierten Abbruchkriterien wurden die Mäuse euthanasiert (= Überlebenszeit) und die Gehirne kryokonserviert. Im Anschluss wurden Gefrierschnitte immunhistologisch angefärbt und die mittlere Anzahl proliferierender Zellen (Ki-67) sowie die Vaskularisierung (CD31) im Tumor ermittelt.
Die statistische Auswertung erfolgte mit n = 10 Tieren je Behandlungsgruppe mittels Mann-Whitney-Test (medianes Überleben) bzw. zweiseitigem T-Test (Ki-67; CD31) zur unbehandelten Kontrollgruppe.
Ergebnis:
Zum Behandlungsstart war eine Tumorgröße von 1 mm nicht überschritten, was durch wöchentliche MRT-Untersuchungen (1-Tesla-Kleintier-MRT/PET Gerät Mediso) nachgewiesen wurde. Die Überlebensanalyse zeigte eine signifikante Verlängerung des medianen Überlebens nach multimodaler Behandlung (RT, Decitabin, Abacavir; 66 ± 9 Tage) vs. der unbehandelten Kontrollgruppe (44 ± 2 Tage) und Bestrahlung (50 ± 1 Tage). Sowohl die Behandlung mit RT+Decitabin (55 ± 3 Tage), als auch mit RT+Abacavir (59 ± 6 Tage), zeigte eine signifikante Überlebenszeitverlängerung vs. Kontrolle, aber nicht vs. RT. Die Proliferation und die Vaskularisierung waren in den multimodal behandelten gegenüber den Kontrolltumoren signifikant (p ≤ 0,05) um 15 % bzw. 14 % verringert.
Schlussfolgerung:
Die multimodale Therapie mit Radiotherapie, Decitabin und Abacavir konnte das Überleben von Mäusen mit orthotopischem Gruppe-3-Medulloblastom signifikant verlängern. Die Therapie zeigt damit klinisch relevantes Potential, welches wir derzeit im Shh/p53-mutierten MB-Mausmodell evaluieren.
Fördermittel:
Das Projekt wird durch die Else Kröner-Fresenius-Stiftung (2016_A184) und die Janssen-Cilag GmbH (DEC-I-17-DEU-001-V01) unterstützt.

Keywords: Medulloblastome; Tri-Therapie; Radiotherapie; Decitabin; Abcavir

  • Poster
    26. Jahrestagung der Deutschen Gesellschaft für Radioonkologie, 25.-28.06.2020, Wiesbaden, Deutschland

Permalink: https://www.hzdr.de/publications/Publ-30468
Publ.-Id: 30468


Imaging of current induced Néel vector switching in antiferromagnetic Mn2Au

Bodnar, S. Y.; Filianina, M.; Bommanaboyena, S. P.; Forrest, T.; Maccherozzi, F.; Sapozhnik, A. A.; Scurschii, I.; Kläui, M.; Jourdan, M.

The effects of current induced Néel spin-orbit torques on the antiferromagnetic domain structure of epitaxial Mn2Au thin films were investigated by x-ray magnetic linear dichroism–photoemission electron microscopy. We observed current induced switching of antiferromagnetic domains essentially corresponding to morphological features of the samples. Reversible as well as irreversible Néel vector reorientation was obtained in different parts of the samples and the switching of up to 30% of all domains in the field of view of 10 μm is demonstrated. Our direct microscopical observations are compared to and fully consistent with anisotropic magnetoresistance effects previously attributed to current induced Néel vector switching in Mn2Au.

Permalink: https://www.hzdr.de/publications/Publ-30467
Publ.-Id: 30467


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