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Paper detail

Polarization freezing of 10000 optically-cooled nuclear spins by coupling to a single electron

The nature of the nano-scale environment presents a major challenge for solid-state implementation of spin-based qubits. In this work, a single electron spin in an optically pumped nanometer-sized III-V semiconductor quantum dot is used to control a macroscopic nuclear spin of several thousand nuclei, freezing its decay and leading to spin life-times exceeding 100 seconds at low temperatures. Few-millisecond-fast optical initialization of the nuclear spin is followed by a slow decay exhibiting random telegraph signals at long delay times, arising from low probability electron jumps out of the dot. The remarkably long spin life-time in a dot surrounded by a densely-packed nuclear spin environment arises from the Knight field created by the resident electron, which leads to suppression of nuclear spin depolarization.

preprint2009arXivOpen access
E. A. ChekhovichM. N. MakhoninJ. Skiba-SzymanskaA. B. KrysaV. D. KulakovskiiV. I. Fal'koM. S. SkolnickA. I. Tartakovskii
cond-mat.mes-hallcond-mat.other
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Open access8 authors2 topics
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E. A. ChekhovichM. N. MakhoninJ. Skiba-SzymanskaA. B. KrysaV. D. KulakovskiiV. I. Fal'koM. S. SkolnickA. I. Tartakovskii

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