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Electrical control and quantum chaos...

Asaad, Serwan.

Electrical control and quantum chaos with a high-spin nucleus in silicon

紀錄類型:	書目-電子資源 : Monograph/item
正題名/作者:	Electrical control and quantum chaos with a high-spin nucleus in siliconby Serwan Asaad.
作者:	Asaad, Serwan.
出版者:	Cham :Springer International Publishing :2021.
面頁冊數:	xvii, 198 p. :ill., digital ;24 cm.
Contained By:	Springer Nature eBook
標題:	Nuclear spin.
電子資源:	https://doi.org/10.1007/978-3-030-83473-9
ISBN:	9783030834739$q(electronic bk.)

Electrical control and quantum chaos with a high-spin nucleus in silicon
Asaad, Serwan.

Electrical control and quantum chaos with a high-spin nucleus in silicon[electronic resource] /by Serwan Asaad. - Cham :Springer International Publishing :2021. - xvii, 198 p. :ill., digital ;24 cm. - Springer theses,2190-5061. - Springer theses..

Introduction -- High-dimensional Spins -- Theory of Donors in Silicon -- Experimental Setup -- 123-Sb Donor Device Characterization.

Nuclear spins are highly coherent quantum objects that were featured in early ideas and demonstrations of quantum information processing. In silicon, the high-fidelity coherent control of a single phosphorus (31-P) nuclear spin I=1/2 has demonstrated record-breaking coherence times, entanglement, and weak measurements. In this thesis, we demonstrate the coherent quantum control of a single antimony (123-Sb) donor atom, whose higher nuclear spin I = 7/2 corresponds to eight nuclear spin states. However, rather than conventional nuclear magnetic resonance (NMR), we employ nuclear electric resonance (NER) to drive nuclear spin transitions using localized electric fields produced within a silicon nanoelectronic device. This method exploits an idea first proposed in 1961 but never realized experimentally with a single nucleus, nor in a non-polar crystal such as silicon. We then present a realistic proposal to construct a chaotic driven top from the nuclear spin of 123-Sb. Signatures of chaos are expected to arise for experimentally realizable parameters of the system, allowing the study of the relation between quantum decoherence and classical chaos, and the observation of dynamical tunneling. These results show that high-spin quadrupolar nuclei could be deployed as chaotic models, strain sensors, hybrid spin-mechanical quantum systems, and quantum-computing elements using all-electrical controls.

ISBN: 9783030834739$q(electronic bk.)

Standard No.: 10.1007/978-3-030-83473-9doiSubjects--Topical Terms:

229771
Nuclear spin.

LC Class. No.: QC793.3.S6 / A73 2021

Dewey Class. No.: 539.725

Electrical control and quantum chaos with a high-spin nucleus in silicon
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505 0 $a Introduction -- High-dimensional Spins -- Theory of Donors in Silicon -- Experimental Setup -- 123-Sb Donor Device Characterization.
520 $a Nuclear spins are highly coherent quantum objects that were featured in early ideas and demonstrations of quantum information processing. In silicon, the high-fidelity coherent control of a single phosphorus (31-P) nuclear spin I=1/2 has demonstrated record-breaking coherence times, entanglement, and weak measurements. In this thesis, we demonstrate the coherent quantum control of a single antimony (123-Sb) donor atom, whose higher nuclear spin I = 7/2 corresponds to eight nuclear spin states. However, rather than conventional nuclear magnetic resonance (NMR), we employ nuclear electric resonance (NER) to drive nuclear spin transitions using localized electric fields produced within a silicon nanoelectronic device. This method exploits an idea first proposed in 1961 but never realized experimentally with a single nucleus, nor in a non-polar crystal such as silicon. We then present a realistic proposal to construct a chaotic driven top from the nuclear spin of 123-Sb. Signatures of chaos are expected to arise for experimentally realizable parameters of the system, allowing the study of the relation between quantum decoherence and classical chaos, and the observation of dynamical tunneling. These results show that high-spin quadrupolar nuclei could be deployed as chaotic models, strain sensors, hybrid spin-mechanical quantum systems, and quantum-computing elements using all-electrical controls.
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