Magnetization-non-conserving spin-orbit interactions enable quantum fluctuations to stabilize chiral ferromagnetic phases with spontaneous orbital chirality and enhanced thermal Hall effect, contrary to classical predictions of only collinear order.
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Magnetization scaling in YbZn2GaO5 breaks down below 3 K due to collective spinon excitations coupled via emergent gauge interactions in the quantum spin liquid state.
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Fluctuation-driven chiral ferromagnetism
Magnetization-non-conserving spin-orbit interactions enable quantum fluctuations to stabilize chiral ferromagnetic phases with spontaneous orbital chirality and enhanced thermal Hall effect, contrary to classical predictions of only collinear order.
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Scaling Breakdown as a Signature of Spinon-Gauge Interaction in the Quantum Spin Liquid YbZn$_2$GaO$_5$
Magnetization scaling in YbZn2GaO5 breaks down below 3 K due to collective spinon excitations coupled via emergent gauge interactions in the quantum spin liquid state.