All optical quantum control of a spin-quantum state and ultrafast transduction into an electric current

The ability to control and exploit quantum coherence and entanglement drives research across many fields ranging from ultra-cold quantum gases to spin systems in condensed matter. Transcending different physical systems, optical approaches have proven themselves to be particularly powerful, since th...

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Veröffentlicht in:	arXiv.org 2012-12
Hauptverfasser:	Müller, K, Kaldewey, T, Ripszam, R, Wildmann, J S, Bechtold, A, Bichler, M, Koblmüller, G, Abstreiter, G, Finley, J J
Format:	Artikel
Sprache:	eng
Schlagworte:	Circuits Coherence Cold spinning Complex systems Electric contacts Electric currents Entanglement Excitons Optical pulses Optics Physics - Mesoscale and Nanoscale Physics Physics - Quantum Physics Quantum dots Quantum phenomena Quantum theory Stability
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creator	Müller, K Kaldewey, T Ripszam, R Wildmann, J S Bechtold, A Bichler, M Koblmüller, G Abstreiter, G Finley, J J
description	The ability to control and exploit quantum coherence and entanglement drives research across many fields ranging from ultra-cold quantum gases to spin systems in condensed matter. Transcending different physical systems, optical approaches have proven themselves to be particularly powerful, since they profit from the established toolbox of quantum optical techniques, are state-selective, contact-less and can be extremely fast. Here, we demonstrate how a precisely timed sequence of monochromatic ultrafast (~2-5 ps) optical pulses, with a well defined polarisation can be used to prepare arbitrary superpositions of exciton spin states in a semiconductor quantum dot, achieve ultrafast control of the spin-wavefunction without an applied magnetic field and make high fidelity read-out the quantum state in an arbitrary basis simply by detecting a strong (~2-10$ pA) electric current flowing in an external circuit. The results obtained show that the combined quantum state preparation, control and read-out can be performed with a near-unity (>97%) fidelity. Our methods are fully applicable to other quantum systems and have strong potential for scaling to more complex systems such as molecules and spin-chains.
doi_str_mv	10.48550/arxiv.1212.2993
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subjects	Circuits Coherence Cold spinning Complex systems Electric contacts Electric currents Entanglement Excitons Optical pulses Optics Physics - Mesoscale and Nanoscale Physics Physics - Quantum Physics Quantum dots Quantum phenomena Quantum theory Stability
title	All optical quantum control of a spin-quantum state and ultrafast transduction into an electric current
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