Microwave dressing breaks rotational symmetry in polar-molecule interactions, producing metastable droplet arrays as non-equilibrium states while suppressing the crystalline phase expected for antidipolar cases.
Supersolid phases in ultracold gases of mi- crowave shielded polar molecules
3 Pith papers cite this work. Polarity classification is still indexing.
years
2026 3verdicts
UNVERDICTED 3representative citing papers
Programmable non-axisymmetric dipolar interactions select a family of stripe solids rather than a single commensurate order in a hard-core Bose lattice model, as shown by quantum Monte Carlo simulations.
Microwave shielding on the n=1→2 transition prevents collisions between ultracold polar molecules without producing bound states that would enhance three-body recombination.
citing papers explorer
-
Equilibrium and non-equilibrium phases of microwave-dressed polar molecules beyond rotational symmetries
Microwave dressing breaks rotational symmetry in polar-molecule interactions, producing metastable droplet arrays as non-equilibrium states while suppressing the crystalline phase expected for antidipolar cases.
-
Programmable dipolar interaction geometry selects stripe-family order in a molecular lattice quantum simulator
Programmable non-axisymmetric dipolar interactions select a family of stripe solids rather than a single commensurate order in a hard-core Bose lattice model, as shown by quantum Monte Carlo simulations.
-
Microwave shielding of ultracold polar molecules on the transition $\boldsymbol{n=1 \rightarrow 2}$
Microwave shielding on the n=1→2 transition prevents collisions between ultracold polar molecules without producing bound states that would enhance three-body recombination.