Spin jam induced by quantum fluctuations in a frustrated magnet

Since the discovery of spin glasses in dilute magnetic systems, their study has been largely focused on understanding randomness and defects as the driving mechanism. The same paradigm has also been applied to explain glassy states found in dense frustrated systems. Recently, however, it has been th...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2015-09, Vol.112 (37), p.11519-11523
Main Authors: Yang, Junjie, Samarakoon, Anjana, Dissanayake, Sachith, Ueda, Hiroaki, Klich, Israel, Iida, Kazuki, Pajerowski, Daniel, Butch, Nicholas P., Huang, Q., Copley, John R. D., Lee, Seung-Hun
Format: Article
Language:English
Subjects:
Ions
Magnetism
Physical Sciences
Quantum physics
Topology
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Summary:Since the discovery of spin glasses in dilute magnetic systems, their study has been largely focused on understanding randomness and defects as the driving mechanism. The same paradigm has also been applied to explain glassy states found in dense frustrated systems. Recently, however, it has been theoretically suggested that different mechanisms, such as quantum fluctuations and topological features, may induce glassy states in defectfree spin systems, far from the conventional dilute limit. Here we report experimental evidence for existence of a glassy state, which we call a spin jam, in the vicinity of the clean limit of a frustrated magnet, which is insensitive to a low concentration of defects. We have studied the effect of impurities on SrCr9pGa12-9pO19[SCGO(p)], a highly frustrated magnet, in which the magnetic Cr3+(s= 3/2) ions form a quasi-2D triangular system of bipyramids. Our experimental data show that as the nonmagnetic Ga3+impurity concentration is changed, there are two distinct phases of glassiness: an exotic glassy state, which we call a spin jam, for the high magnetic concentration region (p> 0.8) and a cluster spin glass for lower magnetic concentration (p< 0.8). This observation indicates that a spin jam is a unique vantage point from which the class of glassy states of dense frustrated magnets can be understood.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1503126112