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Magnetic ground state of the frustrated spin-1/2 chain compound β-TeVO₄ at high magnetic fields

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arxiv 1909.07085 v1 pith:DMQXBU5R submitted 2019-09-16 cond-mat.str-el

Magnetic ground state of the frustrated spin-1/2 chain compound β-TeVO₄ at high magnetic fields

classification cond-mat.str-el
keywords statefieldfrustratedmagneticspin-1betachainmagnetization
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Frustrated spin-1/2 chains, despite the apparent simplicity, exhibit remarkably rich phase diagram comprising vector-chiral (VC), spin-density-wave (SDW) and multipolar/spin-nematic phases as a function of the magnetic field. Here we report a study of $\beta$-TeVO$_4$, an archetype of such compounds, based on magnetization and neutron diffraction measurements up to 25 T. We find the transition from the helical VC ground state to the SDW state at $\sim$3 T for the magnetic field along the $a$ and $c$ crystal axes, and at $\sim$9 T for the field along the $b$ axis. The high-field (HF) state, existing above $\sim$18 T, i.e., above $\sim$1/2 of the saturated magnetization, is an incommensurate magnetically ordered state and not the spin-nematic state, as theoretically predicted for the isotropic frustrated spin-1/2 chain. The HF state is likely driven by sizable interchain interactions and symmetric intrachain anisotropies uncovered in previous studies. Consequently, the potential existence of the spin nematic phase in $\beta$-TeVO$_4$ is limited to a narrow field range, i.e., a few tenths of a tesla bellow the saturation of the magnetization, as also found in other frustrated spin-1/2 chain compounds.

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