Signatures for spinons in the quantum spin liquid candidate Ca10Cr7 O28

Jonas Sonnenschein; Christian Balz; Ulrich Tutsch; Michael Lang; Hanjo Ryll; Jose A. Rodriguez-Rivera; A. T.M.Nazmul Islam; Bella Lake; Johannes Reuther

doi:10.1103/PhysRevB.100.174428

Signatures for spinons in the quantum spin liquid candidate Ca10Cr7 O28

Jonas Sonnenschein
, Christian Balz
, Ulrich Tutsch
, Michael Lang
, Hanjo Ryll
, Jose A. Rodriguez-Rivera
, A. T.M.Nazmul Islam
, Bella Lake
, Johannes Reuther

Spectroscopy

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

We present new experimental lowerature heat capacity and detailed dynamical spin-structure factor data for the quantum spin-liquid candidate material Ca10Cr7O28. The measured heat capacity shows an almost-perfect linear temperature dependence in the range 0.1Kâ‰Tâ‰0.5K, reminiscent of fermionic spinon degrees of freedom. The spin-structure factor exhibits two energy regimes of strong signal which display rather different but solely diffuse scattering features. We theoretically describe these findings by an effective spinon-hopping model which crucially relies on the existence of strong ferromagnetically coupled triangles in the system. Our spinon theory is shown to naturally reproduce the overall weight distribution of the measured spin-structure factor. Particularly, we argue that various different observed characteristic properties of the spin-structure factor and the heat capacity consistently indicate the existence of a spinon Fermi surface. A closer analysis of the heat capacity at the lowest accessible temperatures hints toward the presence of weak f-wave spinon-pairing terms inducing a small partial gap along the Fermi surface (except for discrete nodal Dirac points) and suggesting an overall Z2 quantum spin-liquid scenario for Ca10Cr7O28.

Original language	English
Article number	174428
Journal	Physical Review B
Volume	100
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevB.100.174428
State	Published - Nov 25 2019

Funding

We thank Nic Shannon and Han Yan for fruitful discussions. C.B. acknowledges support from the US Department of Energy, Office of Science, Basic Energy Sciences, Division of Scientific User Facilities. This work was partially supported by the German Research Foundation within the CRC 183 (project A02), the SFB/TR 49, and project B06 of the SFB 1143 (Project No. 247310070). Access to MACS was provided by the Center for High Resolution Neutron Scattering, a partnership between the National Institute of Standards and Technology and the National Science Foundation under Agreement No. DMR-1508249. APPENDIX:

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title = "Signatures for spinons in the quantum spin liquid candidate Ca10Cr7 O28",

abstract = "We present new experimental lowerature heat capacity and detailed dynamical spin-structure factor data for the quantum spin-liquid candidate material Ca10Cr7O28. The measured heat capacity shows an almost-perfect linear temperature dependence in the range 0.1K{\^a}‰T{\^a}‰0.5K, reminiscent of fermionic spinon degrees of freedom. The spin-structure factor exhibits two energy regimes of strong signal which display rather different but solely diffuse scattering features. We theoretically describe these findings by an effective spinon-hopping model which crucially relies on the existence of strong ferromagnetically coupled triangles in the system. Our spinon theory is shown to naturally reproduce the overall weight distribution of the measured spin-structure factor. Particularly, we argue that various different observed characteristic properties of the spin-structure factor and the heat capacity consistently indicate the existence of a spinon Fermi surface. A closer analysis of the heat capacity at the lowest accessible temperatures hints toward the presence of weak f-wave spinon-pairing terms inducing a small partial gap along the Fermi surface (except for discrete nodal Dirac points) and suggesting an overall Z2 quantum spin-liquid scenario for Ca10Cr7O28.",

author = "Jonas Sonnenschein and Christian Balz and Ulrich Tutsch and Michael Lang and Hanjo Ryll and Rodriguez-Rivera, \{Jose A.\} and Islam, \{A. T.M.Nazmul\} and Bella Lake and Johannes Reuther",

note = "Publisher Copyright: {\textcopyright} 2019 American Physical Society.",

year = "2019",

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doi = "10.1103/PhysRevB.100.174428",

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AU - Sonnenschein, Jonas

AU - Balz, Christian

AU - Tutsch, Ulrich

AU - Lang, Michael

AU - Ryll, Hanjo

AU - Rodriguez-Rivera, Jose A.

AU - Islam, A. T.M.Nazmul

AU - Lake, Bella

AU - Reuther, Johannes

PY - 2019/11/25

Y1 - 2019/11/25

N2 - We present new experimental lowerature heat capacity and detailed dynamical spin-structure factor data for the quantum spin-liquid candidate material Ca10Cr7O28. The measured heat capacity shows an almost-perfect linear temperature dependence in the range 0.1Kâ‰Tâ‰0.5K, reminiscent of fermionic spinon degrees of freedom. The spin-structure factor exhibits two energy regimes of strong signal which display rather different but solely diffuse scattering features. We theoretically describe these findings by an effective spinon-hopping model which crucially relies on the existence of strong ferromagnetically coupled triangles in the system. Our spinon theory is shown to naturally reproduce the overall weight distribution of the measured spin-structure factor. Particularly, we argue that various different observed characteristic properties of the spin-structure factor and the heat capacity consistently indicate the existence of a spinon Fermi surface. A closer analysis of the heat capacity at the lowest accessible temperatures hints toward the presence of weak f-wave spinon-pairing terms inducing a small partial gap along the Fermi surface (except for discrete nodal Dirac points) and suggesting an overall Z2 quantum spin-liquid scenario for Ca10Cr7O28.

AB - We present new experimental lowerature heat capacity and detailed dynamical spin-structure factor data for the quantum spin-liquid candidate material Ca10Cr7O28. The measured heat capacity shows an almost-perfect linear temperature dependence in the range 0.1Kâ‰Tâ‰0.5K, reminiscent of fermionic spinon degrees of freedom. The spin-structure factor exhibits two energy regimes of strong signal which display rather different but solely diffuse scattering features. We theoretically describe these findings by an effective spinon-hopping model which crucially relies on the existence of strong ferromagnetically coupled triangles in the system. Our spinon theory is shown to naturally reproduce the overall weight distribution of the measured spin-structure factor. Particularly, we argue that various different observed characteristic properties of the spin-structure factor and the heat capacity consistently indicate the existence of a spinon Fermi surface. A closer analysis of the heat capacity at the lowest accessible temperatures hints toward the presence of weak f-wave spinon-pairing terms inducing a small partial gap along the Fermi surface (except for discrete nodal Dirac points) and suggesting an overall Z2 quantum spin-liquid scenario for Ca10Cr7O28.

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Signatures for spinons in the quantum spin liquid candidate Ca10Cr7 O28

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