Fractional quantum Hall (FQH) states are known for their robust topological order and
possess properties that are appealing for applications in fault-tolerant quantum computing …

Strong mutual interaction which correlates elementary excitations of quantum matter plays a
key role in a range of emergent phenomena, from binding and condensation to quantum …

Projective measurements in random quantum circuits lead to a rich breadth of entanglement
phases and extend the realm of nonunitary quantum dynamics. Here, we explore the …

Although quantum simulation can give insight into elusive or intractable physical
phenomena, many quantum simulators are unavoidably limited in the models they mimic …

We study light-matter interactions in the bulk of a two-dimensional photonic lattice system,
where photons are subject to the combined effect of a synthetic magnetic field and an …

Recent atomic physics experiments and numerical works have reported complementary
signatures of the emergence of a topological quantum spin liquid in models with blockade …

Arrays of highly excited Rydberg atoms can be used as powerful quantum simulation
platforms. Here, we introduce an approach that makes it possible to implement fully …

Due to their immense representative power, neural network quantum states (NQS) have
gained significant interest in current research. In recent advances in the field of NQS, it has …

We examine topological phases and symmetry-protected electronic edge states in the
context of a Rydberg composite: a Rydberg atom interfaced with a structured arrangement of …

We investigate the nature of quantum phases arising in chiral interacting Hamiltonians
recently realized in Rydberg atom arrays. We classify all possible fermionic chiral spin …