Related papers: Relationship between spinons and magnetic fields in a fractionalized state

Relationship between spinons and magnetic fields in a fractionalized state

URL: http://arxiv.org/abs/2408.13665v2
Date: Tue, 19 Nov 2024 00:13:02 GMT
Title: Relationship between spinons and magnetic fields in a fractionalized state
Authors: Yu Zhang, Hengdi Zhao, Tristan R. Cao, Rahul Nandkishore, Gang Cao,
Abstract summary: We find application of magnetic fields up to 14 T below 150 mK induces an abrupt rise in the heat capacity by as much as 5000%. We propose the steep rise in the heat capacity (and thus entropy) at milli-Kelvin temperatures and strong magnetic fields announces a field-induced localization of spinons.
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Abstract: The 4d-electron trimer lattice Ba4Nb1-xRu3+xO12 is believed to feature a heavy spinon Fermi surface that underpins both a quantum spin liquid (QSL) and an adjacent heavy-fermion strange metal (HFSM) phase, depending on Nb content. Itinerant spinons act as heat carriers that render the charge-insulating QSL a much better thermal conductor than the HFSM [1]. We find application of magnetic fields up to 14 T below 150 mK induces an abrupt rise in the heat capacity by as much as 5000% and breaks the signature linear temperature dependences of the heat capacity of both phases. In contrast, the AC magnetic susceptibility and the electrical resistivity are insensitive to applied fields up to 14 T over the same milli-Kelvin temperature range, whereas field depresses the thermal conductivity by up to 40% at temperatures below 4 K. These complex phenomena imply applied magnetic field drastically alters the spinons at low temperatures and demand new physics: We propose the steep rise in the heat capacity (and thus entropy) at milli-Kelvin temperatures and strong magnetic fields announces a field-induced localization of spinons.

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