Contact

Coordinator
PD Dr. Peter Zahn

Phone: +49 351 260 3121
E-mail: nanonet@hzdr.de

Spokesperson
PD Dr. Artur Erbe

Phone: +49 351 260 2366
E-mail: a.erbe@hzdr.de

Deputy spokesperson
Prof. Dr. Gianaurelio Cuniberti

Phone: +49 351 463 31414
E-mail: g.cuniberti@tu-dresden.de

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News

2019-01-11
Julian Schütt defended his PhD thesis at TU Dresden, Fac. of Eng.: Congratulations!

2018-12-13
Eunhye Baek defended her PhD thesis at TU Dresden, Fac of Chem.: Congratulations!

2018-10-15
Himani Arora et al., High-mobility band-like charge transport in a semiconducting two-dimensional metal–organic framework appeared in Nature Materials

Events

2019-01-29
Dresden Science Cafe 'Universum' , 2h tram ride, Start 7 p.m. Nöthnitzer Str., Dresden

2019-02-21/22
GraphIn 2019, Madrid

2019-03-31/04-05
Symposium 'Physics of Self-Organization in DNA Nanostructures (SYDN)' @ DPG Meeting 2019, Regensburg

2019-06-25/28
Graphene 2019, Rome

2019-09-18/20
Werkstoffwoche 2019, Dresden,
Symp. 'Bionik & Bioinspirierte Materialien' org. by A. Fery (IPF)

2019-09-16/20
18th Dresden Microelectronics Academy (DMA), TU Dresden

2019-10-08/11
NanoNet International Conference 2019, Dresden

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Dresden Nano Seminar (TUD)

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Acknowledgment

The IHRS NanoNet is funded by the Initiative and Networking Fund of the Helmholtz Association (VH-KO-606).

Magnetic Resonance in Nanostructures

Lecturer:

Dr. Jürgen Lindner, Dr. Kilian Lenz, Dr. Helmut Schultheiss

Course Type:

Block Course, 2 days (ca. 9 h)

Start Date:

16-17 June 2014

Schedule:

Monday, 16.06.2014; 09:15 - 12:45
Tuesday, 17.06.2014; 09:15 - 16:45

Location:

HZDR, Building 712, Room 138 (how to find us)

Summary:

This course gives an overview on magnetic resonance being a phenomenon that is inherently connected with magnetization dynamics in nanostructured magnetic elements. The theoretical background will be reviewed and explained using simple descriptions. We discuss experimental approaches to detect magnetic resonance and show how this method can be adopted to investigate single magnetic nanostructures. The modern approaches comprise the method of microresonators and alternative detection schemes such as optical and electrical detection. A demonstration of detection of magnetic resonance in the lab will be given.

Language:

English

More info:

Course announcement

Detailed information and agenda

Notes:

The IHRS NanoNet cordially invites all interested to attend the course. 
Attendance is free, but due to the limited number of seats registration is required until 09 June 2014.

Registration:

Registrations are closed

Course Material:

Access is limited to registered participants!

Part I - Theory of Spindynamics

Part II - Ferromagnetic Resonance Techniques

Part III - Magnetic Anisotropy & Damping Mechanisms

Part IV - Magneto-Optical Methods for Investigating Spin Dynamics

Contact:

IHRS NanoNet coordinator (nanonet@hzdr.de)