Potential Spin Liquid System Explored with Pulsed Magnetic Fields

Published October 18, 2023

Physical properties of the the spin liquid compound with spins on a honeycomb lattice, Na2Co2TeO6

Scientists investigated a magnetic compound, identifying a possible spin liquid phase in a quantum material that may be a candidate for robust quantum information technologies.

What did scientists discover?

MagLab users mapped out the regions in temperature and magnetic field in which different spin patterns form in Na₂Co₂TeO₆. This compound is a candidate for spin liquid behavior that is expected to be manifested by the cobalt spins. A wide range of measurements in magnetic fields nailed down the different phases and the region of phase space that might be the sought-after spin liquid state.

Why is this important?

Spin liquids are magnets in which the individual spins on each atom do not freeze into static patterns, but instead form a quantum fluctuating state, known as a quantum spin liquid. These spin liquids may show excitations, called ‘quasiparticles’, that are patterns of spins that may be suitable for the storage and manipulation of quantum information. If so, they may offer advantages over other approaches to quantum computing. However, finding and identifying spin liquid states remains a grand challenge.

Who did the research?

Shengzhi Zhang¹, Sangyun Lee¹, Andrew J. Woods², William K. Peria¹, Sean M. Thomas², Roman Movshovich², Eric Brosha², Qing Huang³, Haidong Zhou³, Vivien S. Zapf¹, and Minseong Lee¹

¹National MagLab and Los Alamos National Lab ²Los Alamos National Lab ³University of Tennessee, Knoxville

Why did they need the MagLab?

Perhaps counterintuitively, the short duration of pulsed magnetic fields can be a critically important enabler to realize highly sensitive measurements. Electric polarization can be measured with higher sensitivity in rapidly changing fields, which enables symmetries of the magnetic order to be probed. Magnetocaloric measurements, valuable for detecting phase transitions by measuring changes in magnetic entropy, are also improved by rapidly changing magnetic fields. This experiment is an example where the material did not demand high magnetic fields. Instead, this experiment required unique MagLab techniques that use pulsed magnetic fields in order to achieve sufficiently high sensitivity to map the many phase transitions in the complex phase diagram of this candidate quantum spin liquid material.

Details for scientists

View or download the expert-level Science Highlight, Potential Spin Liquid System Explored with Pulsed Magnetic Fields
Read the full-length publication, Electronic and magnetic phase diagrams of the Kitaev quantum spin liquid candidate Na₂Co₂TeO₆, in Physical Review B

Funding

This research was funded by the following grants: G.S. Boebinger (NSF DMR-2128556); US DOE Quantum Science Center; LANL LDRD; H. D. Zhou (NSF DMR-2003117); W.K.Peria (Seaborg)

For more information, contact Vivien Zapf.