1. Similar ultrafast dynamics of several dissimilar Dirac and Weyl semimetals
- Author
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Mazhar N. Ali, Leslie M. Schoop, Lingxiao Zhao, Keshav M. Dani, Julien Madéo, Bettina V. Lotsch, Zhiqiang Mao, Bryan Berggren, Stuart S. P. Parkin, Skylar Deckoff-Jones, Genfu Chen, Chris Weber, Michael K. L. Man, Thomas C. Ogloza, Madison G. Masten, and Jinyu Liu
- Subjects
Physics ,Condensed Matter - Materials Science ,Photon ,Condensed matter physics ,Dirac (software) ,Materials Science (cond-mat.mtrl-sci) ,FOS: Physical sciences ,Physics::Optics ,General Physics and Astronomy ,02 engineering and technology ,Electron ,021001 nanoscience & nanotechnology ,01 natural sciences ,Massless particle ,Photoexcitation ,symbols.namesake ,Dirac fermion ,0103 physical sciences ,symbols ,010306 general physics ,0210 nano-technology ,Electronic band structure ,Ultrashort pulse - Abstract
Recent years have seen the rapid discovery of solids whose low-energy electrons have a massless, linear dispersion, such as Weyl, line-node, and Dirac semimetals. The remarkable optical properties predicted in these materials show their versatile potential for optoelectronic uses. However, little is known of their response in the picoseconds after absorbing a photon. Here, we measure the ultrafast dynamics of four materials that share non-trivial band structure topology but that differ chemically, structurally, and in their low-energy band structures: ZrSiS, which hosts a Dirac line node and Dirac points; TaAs and NbP, which are Weyl semimetals; and Sr1–yMn1–zSb2, in which Dirac fermions coexist with broken time-reversal symmetry. After photoexcitation by a short pulse, all four relax in two stages, first sub-picosecond and then few-picosecond. Their rapid relaxation suggests that these and related materials may be suited for optical switches and fast infrared detectors. The complex change of refractive index shows that photoexcited carrier populations persist for a few picoseconds.
- Published
- 2017
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