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 …

Van der Waals (vdW) materials at their 2D limit are diverse, flexible, and unique laboratories
to study fundamental quantum phenomena and their future applications. Their novel …

Identifying phase transitions is one of the key challenges in quantum many-body physics.
Recently, machine learning methods have been shown to be an alternative way of localising …

In recent experiments, the light-matter interaction has reached the ultrastrong coupling limit,
which can give rise to dynamical generalizations of spatial symmetries in periodically driven …

We provide a pedagogical technical guide to many of the key theoretical tools and ideas that
underlie work in the field of Floquet engineering. We hope that this document will serve as a …

The quantum kinetic framework provides a versatile method for investigating the dynamical
optical and transport currents of crystalline solids. In this paper, starting from the density …

Motivated by the recent experimental realization of twisted double bilayer graphene (TDBG)
samples, we study, both analytically and numerically, the effects of circularly polarized light …

Motivated by the recent experimental realization of twisted trilayer graphene and the
observed superconductivity that is associated with its flat bands at specific angles, we study …

We discuss the circularly polarized light (of amplitude A 0 and frequency ω) driven
thermoelectric transport properties of type-I and type-II multi-Weyl semimetals (mWSMs) in …

Floquet engineering presents a versatile method of dynamically controlling material
properties. The light-induced Floquet-Bloch bands of graphene feature band gaps, which …