期刊
ADVANCED ELECTRONIC MATERIALS
卷 7, 期 9, 页码 -出版社
WILEY
DOI: 10.1002/aelm.202100079
关键词
electrical measurements; magnetism; nanostructured materials
资金
- US Department of Energy, Office of Science, Office of Basic Energy Sciences [DE-SC0014461]
Geometrically frustrated materials, such as spin ice or kagome lattice, exhibit exotic Hall effect phenomena due to spin chirality. The study explores Hall effect mechanisms in an artificial honeycomb spin ice of Nd-Sn element, revealing a significant enhancement in Hall signal at higher temperatures and distinct increment in Hall resistivity at very modest fields in the antiferromagnetic state of neodymium. The experimental findings suggest the development of a new research vista to study the planar and field induced Hall effects in artificial spin ice.
Geometrically frustrated materials, such as spin ice or kagome lattice, are known to exhibit exotic Hall effect phenomena due to spin chirality. For the first time, Hall effect mechanism is explored in an artificial honeycomb spin ice of Nd-Sn element using Hall probe and polarized neutron reflectivity measurements. In an interesting observation, a strong enhancement in Hall signal at relatively higher temperature of T similar to 20 K is detected. The effect is attributed to the planar Hall effect due to magnetic moment configuration in spin ice state in low field application. In the antiferromagnetic state of neodymium at low temperature, applied field induced coupling between atomic Nd moments and conduction electrons in underlying lattice causes distinct increment in Hall resistivity at very modest field of H similar to 0.015 T. The experimental findings suggest the development of a new research vista to study the planar and the field induced Hall effects in artificial spin ice.
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