Strong correlations and band topology in the kagome flat band material CsCr3Sb5
ORAL
Abstract
Flat band kagome materials present an ideal platform to study the cooperation between strong
correlations and band topology. A flat band develops from destructive interference, which
motivates the consideration of compact localized states and, more precisely, compact molecular
orbitals. This has led to a theoretical description of the correlations in coupled flat and dispersive
bands in terms of a Kondo lattice in the basis of the molecular orbitals; a phase diagram is found
featuring strong quantum fluctuations and metallic quantum criticality [1]. Such a phase diagram
has recently been realized in the chromium based kagome material CsCr3Sb5 which contains a
flat band near the Fermi energy [2], Here, using first principles, we examine the electronic
structure and band topology in this system. We study properties of Wannier orbitals formed from
the flat bands. Using these Wannier orbitals, we construct minimal interacting models and
address both the quantum fluctuations [1] and electronic orders [3].
[1] L. Chen et al., arXiv:2307.09431.
[2] Y. Liu et al., arXiv:2309.13514.
[3] C. Setty et al., arXiv:2105.15204.
correlations and band topology. A flat band develops from destructive interference, which
motivates the consideration of compact localized states and, more precisely, compact molecular
orbitals. This has led to a theoretical description of the correlations in coupled flat and dispersive
bands in terms of a Kondo lattice in the basis of the molecular orbitals; a phase diagram is found
featuring strong quantum fluctuations and metallic quantum criticality [1]. Such a phase diagram
has recently been realized in the chromium based kagome material CsCr3Sb5 which contains a
flat band near the Fermi energy [2], Here, using first principles, we examine the electronic
structure and band topology in this system. We study properties of Wannier orbitals formed from
the flat bands. Using these Wannier orbitals, we construct minimal interacting models and
address both the quantum fluctuations [1] and electronic orders [3].
[1] L. Chen et al., arXiv:2307.09431.
[2] Y. Liu et al., arXiv:2309.13514.
[3] C. Setty et al., arXiv:2105.15204.
*Work at Rice supported by the DOE BES (DE-SC0018197) and AFOSR (FA9550-21-1-0356).
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Presenters
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Ying Li
- Xi'an Jiaotong Univ