Interaction of magnetic fields with spinons in a fractionalized state

Yu Zhang; Hengdi Zhao; Tristan R. Cao; Rahul Nandkishore; Pedro Schlottmann; Lance De Long; Gang Cao

doi:10.1038/s41535-025-00809-9

Interaction of magnetic fields with spinons in a fractionalized state

Yu Zhang
, Hengdi Zhao
, Tristan R. Cao
, Rahul Nandkishore
, Pedro Schlottmann
, Lance De Long
, Gang Cao

Producción científica: Article › revisión exhaustiva

Resumen

The 4d-electron trimer lattice Ba₄Nb₁₋_ₓRu₃₊_ₓO₁₂ exhibits either a quantum spin liquid (QSL) or a heavy-fermion strange metal (HFSM) phase, depending on Nb content. In the QSL state, itinerant spinons act as effective heat carriers, enhancing thermal conductivity. Strikingly, applying a magnetic field up to 14 T causes an abrupt, up-to-5000% increase in heat capacity below 150 mK, disrupting the linear temperature dependence typical of both phases. Meanwhile, AC susceptibility and electrical resistivity remain nearly unchanged, while thermal conductivity drops by up to 40% below 4 K. These results suggest spinons, despite being charge-neutral, are highly sensitive to magnetic fields at low temperatures. We propose that the magnetic field could induce Anderson localization of spinons, creating emergent non-magnetic two-level systems responsible for the Schottky-like anomaly in heat capacity. These findings point to a previously unexplored regime of spinon dynamics, potentially governed by field-induced localization and distinct from conventional magnetic or transport signatures.

Idioma original	English
Número de artículo	86
Publicación	npj Quantum Materials
Volumen	10
N.º	1
DOI	https://doi.org/10.1038/s41535-025-00809-9
Estado	Published - dic 2025

Nota bibliográfica

Publisher Copyright:
© The Author(s) 2025.

Financiación

G.C. thanks Xi Dai, Tai-Kai Ng, Feng Ye, Sandeep Sharma, Minhyea Lee and Longji Cui for useful discussions. Experimental work is supported by National Science Foundation via Grant No. DMR 2204811. Theoretical work by R.N. was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES) under Award # DE-SC0021346.

Financiadores	Número del financiador
Office of Science Programs
U.S. Department of Energy
National Science Foundation Arctic Social Science Program	DMR 2204811
DOE Basic Energy Sciences	DE-SC0021346

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1038/s41535-025-00809-9

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title = "Interaction of magnetic fields with spinons in a fractionalized state",

abstract = "The 4d-electron trimer lattice Ba₄Nb₁₋ₓRu₃₊ₓO₁₂ exhibits either a quantum spin liquid (QSL) or a heavy-fermion strange metal (HFSM) phase, depending on Nb content. In the QSL state, itinerant spinons act as effective heat carriers, enhancing thermal conductivity. Strikingly, applying a magnetic field up to 14 T causes an abrupt, up-to-5000\% increase in heat capacity below 150 mK, disrupting the linear temperature dependence typical of both phases. Meanwhile, AC susceptibility and electrical resistivity remain nearly unchanged, while thermal conductivity drops by up to 40\% below 4 K. These results suggest spinons, despite being charge-neutral, are highly sensitive to magnetic fields at low temperatures. We propose that the magnetic field could induce Anderson localization of spinons, creating emergent non-magnetic two-level systems responsible for the Schottky-like anomaly in heat capacity. These findings point to a previously unexplored regime of spinon dynamics, potentially governed by field-induced localization and distinct from conventional magnetic or transport signatures.",

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AU - Zhang, Yu

AU - Zhao, Hengdi

AU - Cao, Tristan R.

AU - Nandkishore, Rahul

AU - Schlottmann, Pedro

AU - De Long, Lance

AU - Cao, Gang

PY - 2025/12

Y1 - 2025/12

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AB - The 4d-electron trimer lattice Ba₄Nb₁₋ₓRu₃₊ₓO₁₂ exhibits either a quantum spin liquid (QSL) or a heavy-fermion strange metal (HFSM) phase, depending on Nb content. In the QSL state, itinerant spinons act as effective heat carriers, enhancing thermal conductivity. Strikingly, applying a magnetic field up to 14 T causes an abrupt, up-to-5000% increase in heat capacity below 150 mK, disrupting the linear temperature dependence typical of both phases. Meanwhile, AC susceptibility and electrical resistivity remain nearly unchanged, while thermal conductivity drops by up to 40% below 4 K. These results suggest spinons, despite being charge-neutral, are highly sensitive to magnetic fields at low temperatures. We propose that the magnetic field could induce Anderson localization of spinons, creating emergent non-magnetic two-level systems responsible for the Schottky-like anomaly in heat capacity. These findings point to a previously unexplored regime of spinon dynamics, potentially governed by field-induced localization and distinct from conventional magnetic or transport signatures.

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Interaction of magnetic fields with spinons in a fractionalized state

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