Author
Listed:
- Rong Yu
(Rice University)
- Liang Yin
(University of Florida)
- Neil S. Sullivan
(University of Florida)
- J. S. Xia
(University of Florida)
- Chao Huan
(University of Florida)
- Armando Paduan-Filho
(Instituto de Fisica, Universidade de São Paulo)
- Nei F. Oliveira Jr
(Instituto de Fisica, Universidade de São Paulo)
- Stephan Haas
(University of Southern California)
- Alexander Steppke
(Max Planck Institute for Chemical Physics of Solids, Nöthnitzer Strasse 40, 01187 Dresden, Germany)
- Corneliu F. Miclea
(Condensed Matter and Magnet Science, Los Alamos National Laboratory
National Institute for Materials Physics)
- Franziska Weickert
(Condensed Matter and Magnet Science, Los Alamos National Laboratory)
- Roman Movshovich
(Condensed Matter and Magnet Science, Los Alamos National Laboratory)
- Eun-Deok Mun
(Condensed Matter and Magnet Science, Los Alamos National Laboratory)
- Brian L. Scott
(Condensed Matter and Magnet Science, Los Alamos National Laboratory)
- Vivien S. Zapf
(Condensed Matter and Magnet Science, Los Alamos National Laboratory)
- Tommaso Roscilde
(Laboratoire de Physique, Ecole Normale Supérieure de Lyon, CNRS UMR5672, 46 Allée d’Italie, 69364 Lyon, France)
Abstract
The low-temperature states of bosonic fluids exhibit fundamental quantum effects at the macroscopic scale: the best-known examples are Bose–Einstein condensation and superfluidity, which have been tested experimentally in a variety of different systems. When bosons interact, disorder can destroy condensation, leading to a ‘Bose glass’. This phase has been very elusive in experiments owing to the absence of any broken symmetry and to the simultaneous absence of a finite energy gap in the spectrum. Here we report the observation of a Bose glass of field-induced magnetic quasiparticles in a doped quantum magnet (bromine-doped dichloro-tetrakis-thiourea-nickel, DTN). The physics of DTN in a magnetic field is equivalent to that of a lattice gas of bosons in the grand canonical ensemble; bromine doping introduces disorder into the hopping and interaction strength of the bosons, leading to their localization into a Bose glass down to zero field, where it becomes an incompressible Mott glass. The transition from the Bose glass (corresponding to a gapless spin liquid) to the Bose–Einstein condensate (corresponding to a magnetically ordered phase) is marked by a universal exponent that governs the scaling of the critical temperature with the applied field, in excellent agreement with theoretical predictions. Our study represents a quantitative experimental account of the universal features of disordered bosons in the grand canonical ensemble.
Suggested Citation
Rong Yu & Liang Yin & Neil S. Sullivan & J. S. Xia & Chao Huan & Armando Paduan-Filho & Nei F. Oliveira Jr & Stephan Haas & Alexander Steppke & Corneliu F. Miclea & Franziska Weickert & Roman Movshovi, 2012.
"Bose glass and Mott glass of quasiparticles in a doped quantum magnet,"
Nature, Nature, vol. 489(7416), pages 379-384, September.
Handle:
RePEc:nat:nature:v:489:y:2012:i:7416:d:10.1038_nature11406
DOI: 10.1038/nature11406
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