Peter L. Russo scite author profile

Semiconductor electronics has so far been based on the transport of charge carriers while storage of information has mainly relied upon the collective interactions of spins. A new discipline known as spintronics proposes to exploit the strong mutual influence of magnetic and electrical properties in magnetic semiconductors, which promise new types of devices and computer technologies. The mechanism for such phenomena involves the concept of magnetic polarons-microscopic clouds of magnetization composed of charge carriers and neighboring magnetic ions-which determine most of the electrical, magnetic, and optical properties of the material. In spite of the importance of this quasiparticle, its observation remains a formidable challenge. Here we report that, using the positive muon as both a donor center and a local magnetic probe, we have been able to generate and detect the magnetic polaron and determine its size and magnetic moment in the magnetic semiconductor EuS.

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Frustration-driven spin freezing in theS=12fcc perovskiteSr2

Wiebe

et al. 2003

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Magnetic Phase Diagram of Layered Cobalt DioxideLixCoO2

et al. 2007

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The magnetism of LixCoO2 (LCO), which has a similar structure to NaxCoO2 (NCO), has been investigated by muon-spin spectroscopy and susceptibility measurements using samples with x=0.1-1 prepared by an electrochemical reaction. In the x range below 0.75, LCO was found to be Pauli paramagnetic down to 1.8 K, suggesting an intermediate- or weak-coupling regime, although disordered local moments, with volume fractions below approximately 20%, appear at low T for LCO with x > or = 0.5. The phase diagram and interactions of LCO are thus strikingly different from NCO, while the differences cannot be explained simply by structural differences between the two systems.

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Absence of Broken Time-Reversal Symmetry in the Pseudogap State of the High TemperatureLa2−xSrxCuO4Superconductor from Muon-Spin-Relaxation Measurements

et al. 2008

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We have performed zero-field muon-spin-relaxation measurements on single crystals of La(2-x)SrxCuO4 to search for spontaneous currents in the pseudogap state. By comparing measurements on materials across the phase diagram, we put strict upper limits on any possible time-reversal symmetry breaking fields that could be associated with the pseudogap. Comparison between experimental limits and the proposed circulating current states effectively eliminates the possibility that such states exist in this family of materials.

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Peter L. Russo

Phase separation and suppression of critical dynamics at quantum phase transitions of MnSi and (Sr1−xCax)RuO3

Direct observation of the magnetic polaron

Frustration-driven spin freezing in theS=12fcc perovskiteSr2

Magnetic Phase Diagram of Layered Cobalt DioxideLixCoO2

Absence of Broken Time-Reversal Symmetry in the Pseudogap State of the High TemperatureLa2−xSrxCuO4Superconductor from Muon-Spin-Relaxation Measurements

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