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Sep 09, 2019

Unveiling hidden multipolar orders with magnetostriction

Professor YB Kim's group theoretically propose that magnetostriction provides a powerful and novel tool to directly detect higher-order multipolar symmetry breaking. The paper was published today in Nature Communications.

Unveiling hidden multipolar orders with magnetostriction

Image: Fluctuations of hidden order in response to the lattice strain.

Abstract:

Broken symmetries in solids involving higher order multipolar degrees of freedom are historically referred to as“hidden orders”due to the formidable task of detecting them with conventional probes. In this work, we theoretically propose that magnetostriction provides a powerful and novel tool to directly detect higher-order multi polar symmetry breaking—such as the elusive octupolar order—by examining scaling behaviour of length change with respect to an applied magnetic field h. Employing a symmetry-based Landau theory, we focus on the family of Pr-based cage compounds with strongly correlated f-electrons, Pr(Ti,V,Ir)2(Al,Zn)20, whose low energy degrees of freedom are purely higher-order multi poles: quadrupolesO20;22and octupoleTxyz. We demonstrate that a magnetic field along the direction induces a distinct linear-in-h length change below the octupolar ordering temperature. The resulting“magnetostriction coefficient”is directly proportional to the octupolar order para-meter, thus providing clear access to such subtle order parameters.

Read the full article here:

https://www.nature.com/articles/s41467-019-11913-3.epdf?author_access_token=r9ULzcTLpjyMn4-rX8IbatRgN0jAjWel9jnR3ZoTv0MibVQQC7yvrwM6cnrPtym7mzuehGH0_STRQ6uvNqfWs1oz62jntUJxgsHk1rT55Ds2mcrFLSu4bcFnjWzqzz5eF8IJjcW0yHHmVOGcomCLRQ%3D%3D