Muons and magnets

Quantum Field Theory for the Gifted Amateur

Oxford University Press (OUP), 2014

Authors:

Tom Lancaster, Stephen J Blundell

Frustrated Spin Systems (2nd ed.), edited by H.T. Diep

Contemporary Physics Taylor & Francis 55:2 (2014) 148-149

Statistical Mechanics of Magnetic Excitations, From Spin Waves to Stripes and Checkerboards, by Enrico Rastelli

Contemporary Physics Taylor & Francis 55:2 (2014) 152-153

Dipolar ordering in a molecular nanomagnet detected using muon spin relaxation

Physical Review B American Physical Society (APS) 89:14 (2014) 144420

Authors:

FL Pratt, E Micotti, P Carretta, A Lascialfari, P Arosio, T Lancaster, SJ Blundell, AK Powell

Lattice-site-specific spin dynamics in double perovskite Sr2CoOsO6.

Physical review letters 112:14 (2014) 147202

Authors:

Binghai Yan, Avijit Kumar Paul, Sudipta Kanungo, Manfred Reehuis, Andreas Hoser, Daniel M Többens, Walter Schnelle, Robert C Williams, Tom Lancaster, Fan Xiao, Johannes S Möller, Stephen J Blundell, William Hayes, Claudia Felser, Martin Jansen

Abstract:

Magnetic properties and spin dynamics have been studied for the structurally ordered double perovskite Sr2CoOsO6. Neutron diffraction, muon-spin relaxation, and ac-susceptibility measurements reveal two antiferromagnetic (AFM) phases on cooling from room temperature down to 2 K. In the first AFM phase, with transition temperature TN1=108  K, cobalt (3d7, S=3/2) and osmium (5d2, S=1) moments fluctuate dynamically, while their average effective moments undergo long-range order. In the second AFM phase below TN2=67  K, cobalt moments first become frozen and induce a noncollinear spin-canted AFM state, while dynamically fluctuating osmium moments are later frozen into a randomly canted state at T≈5  K. Ab initio calculations indicate that the effective exchange coupling between cobalt and osmium sites is rather weak, so that cobalt and osmium sublattices exhibit different ground states and spin dynamics, making Sr2CoOsO6 distinct from previously reported double-perovskite compounds.