ELBE List of Publications
The variety of research at ELBE is demonstrated by the lists of recent publications resulting from experiments at ELBE:
- Machine physics(1)
- FELBE(2)
- γELBE(3)
- Detector development(4)
- pELBE(5)
- nELBE(6)
- Radiation physics(7)
- TELBE(8)
Free electron laser (FELBE)
Ultrashort pulses of intense coherent infrared and THz (4-250 µm) from two Free Electron Lasers (FEL) provide an ideal tool for studying ultrafast electronic and structural dynamics in matter. The FEL beam is directed to endstations in several experimental labs, as well as to the neighboring high-field magnet lab (HLD), and a dedicated lab for nanoscale imaging by s-SNOM. Visit the FELBE pages for more information.
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Bremsstrahlung (γELBE)
Bremsstrahlung (up to 20 MeV) is available in the nuclear physics cave. Polarized radiation can also be provided.The time structure of the Bremsstrahlung radiation is defined by the electron beam which has to be operated in the micropulse mode. The interval between the pulses can vary between 77 ns and 1000 ns.
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Neutrons (nELBE)
nELBE is a neutron time-of-flight system with neutron energies between 100 keV and 10 MeV.
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Superradiant THz source (TELBE)
The TELBE facility provides intense, frequency-tunable and CEP stable THz pulses ranging from 0.1 THz to 2.5 THz, typically used for the excitation of nonlinear dynamics in matter. It offers THz pulse energies up to 10 µJ at repetition rates from single shot to hundreds of kHz. Ultrafast THz-driven processes can be probed with femtosecond timing resolution using a variety of laser-based techniques.
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Positrons (pELBE)
Materials research with positrons can be performed at EPOS, which consists of three subsystems for mono-energetic positron spectroscopy (MePS), gamma-induced positron spectroscopy (GiPS) and conventional positron spectroscopy using β+ radiation.
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Radiation physics
The high flexibility of ELBE beam parameters allows unique precise radiobiological experiments. Dose application characteristics can be studied for a multitude of radiotherapy accelerators, ranging from the conventional, quasi-continuous dose delivery over minutes to novel flexible ultra-high dose rate (UHDR) beam delivery within micro- to milliseconds. This enables the direct radiobiological comparison of reference and UHDR irradiation regimes at a single machine, eliminating dose response bias between experiments due to different setups, dosimetry, and experiment time point.
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