Could one make a diamond-based quantum computer?

We assess routes to a diamond-based quantum computer, where we specifically look towards scalable devices, with at least 10 linked quantum gates. Such a computer should satisfy the deVincenzo rules and might be used at convenient temperatures. The specific examples that we examine are based on the o...

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Veröffentlicht in:	Journal of physics. Condensed matter 2009-09, Vol.21 (36), p.364222-364222 (10)
Hauptverfasser:	Stoneham, A Marshall, Harker, A H, Morley, Gavin W
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Sprache:	eng
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creator	Stoneham, A Marshall Harker, A H Morley, Gavin W
description	We assess routes to a diamond-based quantum computer, where we specifically look towards scalable devices, with at least 10 linked quantum gates. Such a computer should satisfy the deVincenzo rules and might be used at convenient temperatures. The specific examples that we examine are based on the optical control of electron spins. For some such devices, nuclear spins give additional advantages. Since there have already been demonstrations of basic initialization and readout, our emphasis is on routes to two-qubit quantum gate operations and the linking of perhaps 10-20 such gates. We analyse the dopant properties necessary, especially centres containing N and P, and give results using simple scoping calculations for the key interactions determining gate performance. Our conclusions are cautiously optimistic: it may be possible to develop a useful quantum information processor that works above cryogenic temperatures.
doi_str_mv	10.1088/0953-8984/21/36/364222
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title	Could one make a diamond-based quantum computer?
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