Probing holographic flat bands at finite density

Grandi, Nicolás

Pontificia Universidad Católica de Chile

Ir al sitio UC

ADMISION

Covid-19

Medios

Biblioteca

Donaciones

Mi Portal UC

Correo
- Correo UC
- Correo GMAIL UC

Información

Tipo de documentoartículo

Documentos de este título

13130_2024_Article_22539.pdf

Datos investigador

Grandi, Nicolás Juričić, Vladimir Salazar Landea, Ignacio Soto Garrido, Rodrigo

Altmetric

Comparte este registro

Flat band electronic systems exhibit a rich landscape of correlation-driven phases, both at the charge neutrality and finite electronic density, featuring exotic electromagnetic and thermodynamic responses. Motivated by these developments, in this paper, we explicitly include the effects of the chemical potential in a holographic model featuring approximately flat bands. In particular, we explore the phase diagram of this holographic flat band system as a function of the chemical potential. We find that at low temperatures and densities, the system features a nematic phase, transitioning into the Lifshitz phase as the chemical potential or temperature increases. To further characterize the ensuing phases, we investigate the optical conductivity and find that this observable shows strong anisotropies in the nematic phase.

Registro Sencillo
Registro Completo

Autor	Grandi, Nicolás Juričić, Vladimir Salazar Landea, Ignacio Soto Garrido, Rodrigo
Título	Probing holographic flat bands at finite density
Revista	Journal of High Energy Physics
ISSN electrónico	1029-8479
Volumen	2024
Número de artículo	30
Página inicio	1
Página final	11
Fecha de publicación	2024
Cómo citar este documento	Journal of High Energy Physics. 2024 Jan 08;2024(1):30
Resumen	Flat band electronic systems exhibit a rich landscape of correlation-driven phases, both at the charge neutrality and finite electronic density, featuring exotic electromagnetic and thermodynamic responses. Motivated by these developments, in this paper, we explicitly include the effects of the chemical potential in a holographic model featuring approximately flat bands. In particular, we explore the phase diagram of this holographic flat band system as a function of the chemical potential. We find that at low temperatures and densities, the system features a nematic phase, transitioning into the Lifshitz phase as the chemical potential or temperature increases. To further characterize the ensuing phases, we investigate the optical conductivity and find that this observable shows strong anisotropies in the nematic phase.
Derechos	acceso abierto
Licencia	CC BY 4.0 DEED Attribution 4.0 International
Agencia financiadora	ANID/ACT210100 (R.S.-G. and V.J.) Swedish Research Council Grant No. VR 2019-04735 (V.J.) Fondecyt (Chile) Grant No. 1200399 (R.S.-G.) and No. 1230933 (V.J.) PUE 084 “Búsqueda de Nueva Física”
DOI	10.1007/JHEP01(2024)030
Enlace	https://doi.org/10.1007/JHEP01(2024)030 https://repositorio.uc.cl/handle/11534/80910
Id de publicación en WoS	WOS:001137951900001
Palabra clave	Holography and Condensed Matter Physics (AdS/CMT) AdS-CFT
Temática	Matemática física y química
Tipo de documento	artículo