Multi-MHz time-of-flight momentum microscopy

• https://www.cells.es/es/actualidad/eventos/eventos-publicos-de-alba/multi-mhz-time-of-flight-momentum-microscopy
• Multi-MHz time-of-flight momentum microscopy
• 2017-07-21T12:30:00+02:00
• 2017-07-21T13:30:00+02:00
• Christian Tusche from Forschungszentrum Jülich GmbH and Fakultät für Physik, Universität Duisburg-Essen. Gemany

Qué

events

Cuándo

Jul 21, 2017
de 12:30 a 13:30 (Europe/Madrid / UTC200)

Dónde

Sincrotrón ALBA, Marie Curie Briefing room

Nombre

Inma Hernandez

Teléfono de contacto

935924389

Asistentes

NOTE: If you are interested in attending, please contact Inma Hernández with your Identity Card number and name to obtain the ALBA access.

Enlace del evento

Página web externa

Agregar evento al calendario

iCal

Abstract

By using a photoelectron emission microscope (PEEM) we commonly look at strongly magnified images of a sample's surface in real space. Likewise, a momentum microscope utilizes the principles of electron microscopy to form a high resolution image of the distribution of electronic states in reciprocal (i.e., momentum-) space [1]. Such two- dimensional (kx,ky) maps of the photoelectron distribution represent sections through the valence electronic states in the full surface Brillouin zone, and give a comprehensive and intuitive access to the electronic properties of a material. Together with advanced time-of- flight (ToF) detection schemes the full band information becomes available within minutes.

Of particular importance is the spin of the electron, that gives rise to phenomena like ferromagnetism, superconductivity, spin-polarized surface states, and recently, the discovery of new material classes with complex spin textures like topological insulators. With the introduction of imaging spin analyzers [2] the efficiency of spin-resolved measurements experienced a tremendous boost, such that the electron spin now becomes routinely accessible in a photoemission experiment.

We will discuss applications and prospects, including spin-textures of topological materials [3], spin-orbit- and exchange-interaction in ferromagnets [4], and rapid band structure mapping by multi-MHz ToF momentum microscopy [5]. The results pave the way to comprehensive 3D band mapping with complete wave-vector-, spin-, and time-resolution at next generation light sources.

References

[1] C. Tusche, A. Krasyuk, J. Kirschner, Ultramicroscopy 159, p. 520 (2015)

[2] C. Tusche, M. Ellguth, A. A. Ünal, C.-T. Chiang et al., Appl. Phys. Lett. 99, 032505 (2011) [3] H. Maaß, H. Bentmann, C. Seibel, C. Tusche et al., Nat. Commun. 7, 11621 (2016)

[4] M. Ellguth, C. Tusche, J. Kirschner, Phys. Rev. Lett., 115, 266801 (2015)

[5] C. Tusche, P. Goslawski, D. Kutnyakhov, M. Ellguth et al., Appl. Phys. Lett. 108, 261602 (2016)