A graph-theoretic method systematically constructs quantum many-body scars in frustrated Rydberg lattices via type-I and type-II mechanisms, with numerical demonstration of an exponential family of scarred trajectories on the hexagonal lattice.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
years
2026 3representative citing papers
First experimental signatures of asymptotic quantum many-body scars on a trapped-ion simulator show thermalization times increasing with system size up to 20 qubits.
citing papers explorer
-
Systematic construction of quantum many-body scars in frustrated Rydberg arrays
A graph-theoretic method systematically constructs quantum many-body scars in frustrated Rydberg lattices via type-I and type-II mechanisms, with numerical demonstration of an exponential family of scarred trajectories on the hexagonal lattice.
-
Dynamical signatures of conventional and asymptotic quantum many-body scars on a trapped ion simulator
First experimental signatures of asymptotic quantum many-body scars on a trapped-ion simulator show thermalization times increasing with system size up to 20 qubits.
- Finite-temperature crossover from coherent magnons to energy superdiffusion in the PXP model