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Spin, orbital, Weyl and other glasses in topological superfluids

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arxiv 1806.08177 v3 pith:H6QGPQ3Y submitted 2018-06-21 cond-mat.dis-nn cond-mat.other

Spin, orbital, Weyl and other glasses in topological superfluids

classification cond-mat.dis-nn cond-mat.other
keywords topologicalglassglassesspinsuperfluidaerogelanisotropydistributed
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One of the most spectacular discoveries made in superfluid $^3$He confined in a nanostructured material like aerogel or nafen was the observation of the destruction of the long-range orientational order by a weak random anisotropy. The quenched random anisotropy provided by the confining material strands produces several different glass states resolved in NMR experiments in the chiral superfluid $^3$He-A and in the time-reversal-invariant polar phase. The smooth textures of spin and orbital order parameters in these glasses can be characterized in terms of the randomly distributed topological charges, which describe skyrmions, spin vortices and hopfions. In addition, in these skyrmion glasses the momentum-space topological invariants are randomly distributed in space. The Chern mosaic, Weyl glass, torsion glass and other exotic topological sates are examples of close connections between the real-space and momentum-space topologies in superfluid $^3$He phases in aerogel.

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