Quantum percolation of monopole paths and the response of quantum spin ice

We consider quantum spin ice in a temperature regime in which its response is dominated by the coherent motion of a dilute gas of monopoles. The hopping amplitude of a monopole is sensitive to the configuration of its surrounding spins, taken to be quasi-static on the relevant timescales. This leads to well-known blocked directions in the monopole motion; we find that these are sufficient to reduce the coherent propagation of monopoles to quantum diffusion. This result is robust against disorder, as a direct consequence of the ground-state degeneracy, which disrupts the quantum interference processes needed for weak localization. Moreover, recent work [Tomasello et al., Phys. Rev. Lett. 123, 067204 (2019)] has shown that the monopole hopping amplitudes are roughly bimodal: for $\approx 1/3$ of the flippable spins surrounding a monopole, these amplitudes are extremely small. We exploit this structure to construct a theory of quantum monopole motion in spin ice. In the limit where the slow hopping terms are set to zero, the monopole wavefunctions appear to be fractal; we explain this observation via a mapping to quantum percolation on trees. The fractal, non-ergodic nature of monopole wavefunctions manifests itself in the low-frequency behavior of monopole spectral functions, and is consistent with experimental observations.

[1]  Daniel G. Nocera,et al.  Fractionalized excitations in the spin-liquid state of a kagome-lattice antiferromagnet , 2012, Nature.

[2]  J. W. Essam,et al.  Some Cluster Size and Percolation Problems , 1961 .

[3]  Gavin Armstrong In a spin , 2008 .

[4]  Andrew D. King,et al.  Qubit spin ice , 2020, Science.

[5]  N. P. Armitage,et al.  A measure of monopole inertia in the quantum spin ice Yb2Ti2O7 , 2015, Nature Physics.

[6]  R. Moessner,et al.  Spin Ice, Fractionalization, and Topological Order , 2011, 1112.3793.

[7]  M. Gingras,et al.  Quantum spin ice: a search for gapless quantum spin liquids in pyrochlore magnets , 2013, Reports on progress in physics. Physical Society.

[8]  S. Blundell,et al.  Magnetic monopole noise , 2019, Nature.

[9]  Anomalous magnetic noise in an imperfectly flat landscape in the topological magnet Dy2Ti2O7 , 2021, Proceedings of the National Academy of Sciences.

[10]  J. Knolle,et al.  Physics of the Kitaev Model: Fractionalization, Dynamic Correlations, and Material Connections , 2017, 1705.01740.

[11]  D. McMorrow,et al.  Magnetic Coulomb Phase in the Spin Ice Ho2Ti2O7 , 2009, Science.

[12]  G. Ehlers,et al.  Continuous excitations of the triangular-lattice quantum spin liquid YbMgGaO4 , 2016, Nature Physics.

[13]  L. Balents Spin liquids in frustrated magnets , 2010, Nature.

[14]  小谷 正雄 日本物理学会誌及びJournal of the Physical Society of Japanの月刊について , 1955 .

[15]  富野 康日己,et al.  Annual review 腎臓 , 1987 .

[16]  Swee-Ping Chia,et al.  AIP Conference Proceedings , 2008 .

[17]  James S. Langer,et al.  Annual review of condensed matter physics , 2010 .

[18]  W. De Roeck,et al.  Asymptotic Quantum Many-Body Localization from Thermal Disorder , 2013, 1308.6263.

[19]  N. P. Armitage Inertial effects in systems with magnetic charge , 2017, 1710.11226.

[20]  Markus P. Müller,et al.  Ideal quantum glass transitions: Many-body localization without quenched disorder , 2013, 1309.1082.

[21]  M. M. Mohan Possibility of quasiparticle behaviour in the strongly correlated Hubbard model , 1991 .

[22]  M. Frontzek,et al.  Evidence for a spinon Fermi surface in a triangular-lattice quantum-spin-liquid candidate , 2016, Nature.

[23]  R. Cava,et al.  Quantum spin liquids , 2019, Science.

[24]  R. Moessner,et al.  A Field Guide to Spin Liquids , 2018, Annual Review of Condensed Matter Physics.