CITE.CC academic search helps you expand the influence of your papers.
Abstract
Interacting nuclear spins on a crystalline lattice are commonly believed to be well described within a thermodynamic framework that uses the concept of spin temperature. Demagnetization experiments now challenge this belief, showing that in general the spin-temperature concept fails to describe a nuclear-spin ensemble in a quantum dot when strong quadrupolar interactions are induced by strain. The physics of interacting nuclear spins arranged on a crystalline lattice is generally described using a thermodynamic framework1 and the concept of spin temperature. In the past, experimental studies in bulk solid-state systems have proven this concept to be not only correct2,3 but also vital for the understanding of experimental observations4. Here we show, using demagnetization experiments, that the concept of spin temperature in general fails to describe the mesoscopic nuclear-spin ensemble of a quantum dot. We associate the observed deviations from a thermal spin state with the presence of strong quadrupolar interactions within the quantum dot, which cause significant anharmonicity in the spectrum of the nuclear spins. Strain-induced, inhomogeneous quadrupolar shifts also lead to a complete suppression of angular-momentum exchange between the nuclear-spin ensemble and its environment, resulting in nuclear-spin relaxation times exceeding an hour. Remarkably, the position-dependent axes of the quadrupolar interactions render magnetic-field sweeps inherently non-adiabatic, thereby causing an irreversible loss of nuclear-spin polarization.Cite this article
Maletinsky, P., Kroner, M. & Imamoglu, A. Breakdown of the nuclear-spin-temperature approach in quantum-dot demagnetization experiments. Nature Phys 5, 407–411 (2009). https://doi.org/10.1038/nphys1273 