Polar molecules in topological order

The realization of ultracold polar molecules in laboratories has pushed physics and chemistry to new realms. In particular, these polar molecules offer scientists unprecedented opportunities to explore chemical reactions in the ultracold regime where quantum effects become profound. However, a key question about how two-body losses depend on quantum correlations in interacting many-body systems remains open so far. Here, we present a number of universal relations that directly connect two-body losses to other physical observables, including the momentum distribution and density correlation functions. These relations, which are valid for arbitrary microscopic parameters, such as the particle number, the temperature, and the interaction strength, unfold the critical role of contacts, a fundamental quantity of dilute quantum systems, in determining the reaction rate of quantum reactive molecules in a many-body environment. Our work opens the door to an unexplored area intertwining quantum chemistry; atomic, molecular, and optical physics; and condensed matter physics.

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Abelian topological order of ν=2/5 and 3/7 fractional quantum Hall states in lattice models

Physical Review B ◽

10.1103/physrevb.103.075132 ◽

2021 ◽

Vol 103 (7) ◽

Author(s):

Bartholomew Andrews ◽

Madhav Mohan ◽

Titus Neupert

Keyword(s):

Quantum Hall ◽

Lattice Models ◽

Topological Order ◽

Fractional Quantum ◽

Fractional Quantum Hall ◽

Quantum Hall States ◽

Hall States

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Edge channels of broken-symmetry quantum Hall states in graphene visualized by atomic force microscopy

Nature Communications ◽

10.1038/s41467-021-22886-7 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Sungmin Kim ◽

Johannes Schwenk ◽

Daniel Walkup ◽

Yihang Zeng ◽

Fereshte Ghahari ◽

...

Keyword(s):

Atomic Force Microscopy ◽

Chemical Potential ◽

Quantum Hall ◽

Broken Symmetry ◽

Topological Order ◽

Edge States ◽

Force Microscopy ◽

Atomic Force ◽

Intimate Relation ◽

Boundary Measurements

AbstractThe quantum Hall (QH) effect, a topologically non-trivial quantum phase, expanded the concept of topological order in physics bringing into focus the intimate relation between the “bulk” topology and the edge states. The QH effect in graphene is distinguished by its four-fold degenerate zero energy Landau level (zLL), where the symmetry is broken by electron interactions on top of lattice-scale potentials. However, the broken-symmetry edge states have eluded spatial measurements. In this article, we spatially map the quantum Hall broken-symmetry edge states comprising the graphene zLL at integer filling factors of $${{\nu }}={{0}},\pm {{1}}$$ ν = 0 , ± 1 across the quantum Hall edge boundary using high-resolution atomic force microscopy (AFM) and show a gapped ground state proceeding from the bulk through to the QH edge boundary. Measurements of the chemical potential resolve the energies of the four-fold degenerate zLL as a function of magnetic field and show the interplay of the moiré superlattice potential of the graphene/boron nitride system and spin/valley symmetry-breaking effects in large magnetic fields.

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