Introducción a la química cuántica topológica para la búsqueda de materiales y aplicaciones

Dr Maia G. Vergniory, Donostia International Physics Center, San Sebastiá / IKERBASQUE, Basque Foundation for Science, Bilbao

https://www.sincrotronalba.es/es/actualidad/eventos/eventos-externos/introduccion-a-la-quimica-cuantica-topologica-para-la-busqueda-de-materiales-y-aplicaciones
Introducción a la química cuántica topológica para la búsqueda de materiales y aplicaciones
2019-10-21T12:00:00+02:00
2019-10-21T13:00:00+02:00
Dr Maia G. Vergniory, Donostia International Physics Center, San Sebastiá / IKERBASQUE, Basque Foundation for Science, Bilbao

Cuándo: Oct 21, 2019
de 12:00 a 13:00 (Europe/Madrid / UTC200)
Dónde: Sala de Seminarios ICN2 (UAB)
Nombre: Ana De La Osa
Agregar evento al calendario: iCal

In this talk a new field that classifies all topological crystalline phases of all known materials will be introduced:
Topological Quantum Chemistry (TQC). It links the chemical and symmetry structure of a given material with its topological properties. This field tabulates the data of the 10398 real-space atomic limits of materials, and solves the compatibility relations of electronic bands in momentum space. A material that is not an atomic límit or whose bands do not satisfy the compatibility relations, is a topological insulator/semimetal. We use TQC to find the topological stoichiometric non-magnetic, ``high-quality'' materials in the world. We develop several code which can compute all characters of all symmetries at all high-symmetry points in the Brillouin Zone (BZ).
Using TQC we then develop codes to check which materials are topological. Out of 26938 stoichiometric materials in our filtered ICSD database, we find around 7300 topological materials. For the majority of the ``high-quality'' topological materials, we compute: the topological class, the symmetry(ies) that protects the
topological class, the representations at high symmetry points and the direct gap (for insulators), and the topological index. For topological semimetals we then compute whether the system becomes a topological insulator (whose index/class we compute) upon breaking symmetries - useful for experiments. Our exhaustive
results show that a large proportion of all materials in nature are topological. I will also explain an open-source code and end-user button on the Bilbao Crystallographic Server (http://www.cryst.ehu.es/cgibin/ cryst/programs/topological.pl) which checks the topology of any material and a new materials data base (https://www.topologicalquantumchemistry.com/).

[1] B. Bradlyn, L. Elcoro, J. Cano, M.G. Vergniory, Z. Wang, C. Felser, M.I. Aroyo, B.A. Bernevig, “Topological quantum
chemistry”, Nature 547 (7663), 298-305 (2017).
[2] MG Vergniory, L Elcoro, Zhijun Wang, Jennifer Cano, C Felser, MI Aroyo, B Andrei Bernevig, Barry Bradlyn, “Graph
theory data for topological quantum chemistry”, Phys. Rev. E 96, 023310 (2017)
[3] Barry Bradlyn, L Elcoro, MG Vergniory, Jennifer Cano, Zhijun Wang, C Felser, MI Aroyo, B Andrei Bernevig, “Band
connectivity for topological quantum chemistry: Band structures as a graph theory problem”, Physical Review B 97 (3),
035138 (2017)
[4] Jennifer Cano, Barry Bradlyn, Zhijun Wang, L Elcoro, MG Vergniory, C Felser, MI Aroyo, B Andrei Bernevig, “Building
blocks of topological quantum chemistry: Elementary band representations”, Physical Review B 97 (3), 035139 (2017)
[5] M.G. Vergniory, L. Elcoro, C. Felser, N. Regnault, B.A. Bernevig, Z. Wang , “A complete catalogue of High-Quality
Topological Materials “, Nature 566, 480-485 (2019)