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Lattice Homotopy Constraints on Phases of Quantum Magnets.

Author
Abstract
:

The Lieb-Schultz-Mattis (LSM) theorem and its extensions forbid trivial phases from arising in certain quantum magnets. Constraining infrared behavior with the ultraviolet data encoded in the microscopic lattice of spins, these theorems tie the absence of spontaneous symmetry breaking to the emergence of exotic phases like quantum spin liquids. In this work, we take a new topological perspective on these theorems, by arguing they originate from an obstruction to "trivializing" the lattice under smooth, symmetric deformations, which we call the "lattice homotopy problem." We conjecture that all LSM-like theorems for quantum magnets (many previously unknown) can be understood from lattice homotopy, which automatically incorporates the full spatial symmetry group of the lattice, including all its point-group symmetries. One consequence is that any spin-symmetric magnet with a half-integer moment on a site with even-order rotational symmetry must be a spin liquid. To substantiate the claim, we prove the conjecture in two dimensions for some physically relevant settings.

Year of Publication
:
2017
Journal
:
Physical review letters
Volume
:
119
Issue
:
12
Number of Pages
:
127202
Date Published
:
2017
ISSN Number
:
0031-9007
URL
:
http://link.aps.org/abstract/PRL/v119/p127202
DOI
:
10.1103/PhysRevLett.119.127202
Short Title
:
Phys Rev Lett
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