This article reviews odd-frequency (odd-ω) pairing with a focus on superconducting systems.
Since Berezinskii introduced the concept of odd-frequency order in 1974 it has been viewed …

A hallmark of the phase diagrams of quantum materials is the existence of multiple
electronic ordered states, which, in many cases, are not independent competing phases, but …

Because of their tiny band gaps Dirac materials promise to improve the sensitivity for dark
matter particles in the sub-MeV mass range by many orders of magnitude. We study several …

We analyze the robustness of corner modes in topological photonic crystals, taking a C 6-
symmetric breathing honeycomb photonic crystal as an example. First, we employ …

We present a Mathematica program package MagneticTB, which can generate the tight-
binding model for arbitrary magnetic space group. The only input parameters in MagneticTB …

Learning the global crystal symmetry and interpreting the equivariant information is crucial
for accurately predicting material properties, yet remains to be fully accomplished by existing …

We review recent work on low-frequency Floquet engineering and its application to quantum
materials driven by light, focusing on van der Waals systems hosting Moiré superlattices …

In recent years, there have been rapid advances in the parallel fields of electronic and
photonic topological crystals. Topological photonic crystals in particular show promise for …

The phonon inverse Faraday effect describes the emergence of a dc magnetization due to
circularly polarized phonons. In this work we present a microscopic formalism for the phonon …

High-intensity THz lasers allow for the coherent excitation of individual phonon modes. The
ultrafast control of emergent magnetism by means of phonons opens up new tuning …