TY - JOUR
T1 - Disordered magnetic ground state in a quasi-1-D d 4 columnar iridate Sr3LiIrO6
AU - Bandyopadhyay, Abhisek
AU - Das, Debu
AU - Chakraborty, A.
AU - Bhowal, S.
AU - Kumar, Vinod
AU - Stenning, G. B.G.
AU - Ritter, C.
AU - Adroja, D. T.
AU - Moretti Sala, M.
AU - Efimenko, A.
AU - Meneghini, C.
AU - Bert, F.
AU - Biswas, P. K.
AU - Dasgupta, I.
AU - Saha Dasgupta, T.
AU - Mahajan, A. V.
AU - Ray, Sugata
N1 - Publisher Copyright:
© 2024 The Author(s). Published by IOP Publishing Ltd.
PY - 2024/7/25
Y1 - 2024/7/25
N2 - Spin-orbit coupling offers a large variety of novel and extraordinary magnetic and electronic properties in otherwise ‘ordinary pool’ of heavy ion oxides. Here we present a detailed study on an apparently isolated hexagonal 2H spin-chain d 4 iridate Sr3LiIrO6 with geometric frustration. Our structural studies reveal Li-Ir chemical order with desired stoichiometry in this compound, while x-ray absorption together with x-ray photoemission spectroscopic characterizations establish pure 5+ valence of Ir. We have established a magnetic ground state with finite Ir5+ magnetic moments in this compound, contrary to the anticipated nonmagnetic J eff = 0 state, through combined dc susceptibility, 7 Li nuclear magnetic resonance (NMR), muon spin relaxation (µSR) and ab-initio electronic structure studies. These investigations together with ac magnetic susceptibility and specific heat measurements reveal that despite having noticeable antiferromagnetic correlation among the Ir5+ local moments, this system does not magnetically order down to at least 0.05 K, possibly due to geometrical exchange frustration, arising from the comparable nearest- and next-nearest-neighbor interchain Ir-O-O-Ir superexchange interaction strengths with opposite signs. However, the zero-field µSR analysis shows emergence of a considerable proportion of spin-freezing on top of a spin-fluctuating dynamic magnetic background down to the lowest measured temperature of 1.7 K, possibly due to some inhomogeneity and/or the much stronger intra-column Ir-Ir magnetic exchange interaction strength relative to the inter-column Ir-Ir ones.
AB - Spin-orbit coupling offers a large variety of novel and extraordinary magnetic and electronic properties in otherwise ‘ordinary pool’ of heavy ion oxides. Here we present a detailed study on an apparently isolated hexagonal 2H spin-chain d 4 iridate Sr3LiIrO6 with geometric frustration. Our structural studies reveal Li-Ir chemical order with desired stoichiometry in this compound, while x-ray absorption together with x-ray photoemission spectroscopic characterizations establish pure 5+ valence of Ir. We have established a magnetic ground state with finite Ir5+ magnetic moments in this compound, contrary to the anticipated nonmagnetic J eff = 0 state, through combined dc susceptibility, 7 Li nuclear magnetic resonance (NMR), muon spin relaxation (µSR) and ab-initio electronic structure studies. These investigations together with ac magnetic susceptibility and specific heat measurements reveal that despite having noticeable antiferromagnetic correlation among the Ir5+ local moments, this system does not magnetically order down to at least 0.05 K, possibly due to geometrical exchange frustration, arising from the comparable nearest- and next-nearest-neighbor interchain Ir-O-O-Ir superexchange interaction strengths with opposite signs. However, the zero-field µSR analysis shows emergence of a considerable proportion of spin-freezing on top of a spin-fluctuating dynamic magnetic background down to the lowest measured temperature of 1.7 K, possibly due to some inhomogeneity and/or the much stronger intra-column Ir-Ir magnetic exchange interaction strength relative to the inter-column Ir-Ir ones.
KW - 5d iridates
KW - disordered magnetic state
KW - geometric frustration
KW - spin-orbit coupling
UR - http://www.scopus.com/inward/record.url?scp=85199677027&partnerID=8YFLogxK
U2 - 10.1088/1361-648x/ad63eb
DO - 10.1088/1361-648x/ad63eb
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C2 - 39013404
AN - SCOPUS:85199677027
SN - 0953-8984
VL - 36
JO - Journal of Physics Condensed Matter
JF - Journal of Physics Condensed Matter
IS - 42
M1 - 425804
ER -