Oscillations of the thermal conductivity in the spin-liquid state of α-RuCl3

Peter Czajka; Tong Gao; Max Hirschberger; Paula Lampen-Kelley; Arnab Banerjee; Jiaqiang Yan; David G. Mandrus; Stephen E. Nagler; N. P. Ong

doi:10.1038/s41567-021-01243-x

Oscillations of the thermal conductivity in the spin-liquid state of α-RuCl₃

Peter Czajka, Tong Gao, Max Hirschberger, Paula Lampen-Kelley, Arnab Banerjee, Jiaqiang Yan, David G. Mandrus, Stephen E. Nagler, N. P. Ong

Correlated Electron Materials

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145 Scopus citations

Abstract

In the class of materials called spin liquids^1–3, a magnetically ordered state cannot be attained even at millikelvin temperatures because of conflicting constraints on each spin; for example, from geometric or exchange frustration. The resulting quantum spin-liquid state is currently of intense interest because it exhibits unusual excitations as well as wave-function entanglement. The layered insulator α-RuCl₃ orders as a zigzag antiferromagnet at low temperature in zero magnetic field⁴. The zigzag order is destroyed when a magnetic field is applied parallel to the zigzag axis. At moderate magnetic field strength, there is growing evidence that a quantum spin-liquid state exists. Here we report the observation of oscillations in its thermal conductivity in that field range. The oscillations, whose amplitude is very large within this field range and strongly suppressed on either side, are periodic. This is analogous to quantum oscillations in metals, even though α-RuCl₃ is an excellent insulator with a large gap. As the temperature is raised above 0.5 K, the oscillation amplitude decreases exponentially, anticorrelating with the emergence of an anomalous planar thermal Hall conductivity above approximately 2 K.

Original language	English
Pages (from-to)	915-919
Number of pages	5
Journal	Nature Physics
Volume	17
Issue number	8
DOIs	https://doi.org/10.1038/s41567-021-01243-x
State	Published - Aug 2021

Funding

We thank J. Lin and S. Kim for technical assistance and T. Senthil and I. Sodemann for valuable discussions. P.C. and M.H., and the measurements of \u03BAxx, were supported by a MRSEC award from the US National Science Foundation (DMR 1420541 and DMR 2011750). T.G. and the low-T thermal Hall experiments were supported by the US Department of Energy (DE-SC0017863). A.B. and S.E.N are supported by the DOE, Office of Science, Scientific User Facilities Division. N.P.O. was supported by the Gordon and Betty Moore Foundation\u2019s EPiQS initiative through grant GBMF9466. P.L.-K. and D.G.M. were supported by Moore Foundation\u2019s EPiQS initiative through grant GBMF4416.

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title = "Oscillations of the thermal conductivity in the spin-liquid state of α-RuCl3",

abstract = "In the class of materials called spin liquids1–3, a magnetically ordered state cannot be attained even at millikelvin temperatures because of conflicting constraints on each spin; for example, from geometric or exchange frustration. The resulting quantum spin-liquid state is currently of intense interest because it exhibits unusual excitations as well as wave-function entanglement. The layered insulator α-RuCl3 orders as a zigzag antiferromagnet at low temperature in zero magnetic field4. The zigzag order is destroyed when a magnetic field is applied parallel to the zigzag axis. At moderate magnetic field strength, there is growing evidence that a quantum spin-liquid state exists. Here we report the observation of oscillations in its thermal conductivity in that field range. The oscillations, whose amplitude is very large within this field range and strongly suppressed on either side, are periodic. This is analogous to quantum oscillations in metals, even though α-RuCl3 is an excellent insulator with a large gap. As the temperature is raised above 0.5 K, the oscillation amplitude decreases exponentially, anticorrelating with the emergence of an anomalous planar thermal Hall conductivity above approximately 2 K.",

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AU - Lampen-Kelley, Paula

AU - Banerjee, Arnab

AU - Yan, Jiaqiang

AU - Mandrus, David G.

AU - Nagler, Stephen E.

AU - Ong, N. P.

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Oscillations of the thermal conductivity in the spin-liquid state of α-RuCl₃

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