Characterization of the Si:Se+ spin-photon interface

Silicon is the most developed electronic and photonic technological platform and hosts some of the highest-performance spin and photonic qubits developed to date. A hybrid quantum technology harnessing an efficient spin-photon interface in silicon would unlock considerable potential by enabling ultr...

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Veröffentlicht in:	arXiv.org 2018-09
Hauptverfasser:	DeAbreu, Adam, Bowness, Camille, Abraham, Rohan J S, Medvedova, Alzbeta, Morse, Kevin J, Riemann, Helge, Abrosimov, Nikolay V, Becker, Peter, Pohl, Hans-Joachim, Thewalt, Michael L W, Simmons, Stephanie
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Schlagworte:	Converters Dipole moments Donors (electronic) Energy gap Microwave photonics Optical communication Optoelectronics Phonons Physics - Applied Physics Physics - Quantum Physics Qubits (quantum computing) Silicon
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creator	DeAbreu, Adam Bowness, Camille Abraham, Rohan J S Medvedova, Alzbeta Morse, Kevin J Riemann, Helge Abrosimov, Nikolay V Becker, Peter Pohl, Hans-Joachim Thewalt, Michael L W Simmons, Stephanie
description	Silicon is the most developed electronic and photonic technological platform and hosts some of the highest-performance spin and photonic qubits developed to date. A hybrid quantum technology harnessing an efficient spin-photon interface in silicon would unlock considerable potential by enabling ultra-long-lived photonic memories, distributed quantum networks, microwave to optical photon converters, and spin-based quantum processors, all linked using integrated silicon photonics. However, the indirect bandgap of silicon makes identification of efficient spin-photon interfaces nontrivial. Here we build upon the recent identification of chalcogen donors as a promising spin-photon interface in silicon. We determined that the spin-dependent optical degree of freedom has a transition dipole moment stronger than previously thought (here 1.96(8) Debye), and the T1 spin lifetime in low magnetic fields is longer than previously thought (> 4.6(1.5) hours). We furthermore determined the optical excited state lifetime (7.7(4) ns), and therefore the natural radiative efficiency (0.80(9) %), and by measuring the phonon sideband, determined the zero-phonon emission fraction (16(1) %). Taken together, these parameters indicate that an integrated quantum optoelectronic platform based upon chalcogen donor qubits in silicon is well within reach of current capabilities.
doi_str_mv	10.48550/arxiv.1809.10228
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We furthermore determined the optical excited state lifetime (7.7(4) ns), and therefore the natural radiative efficiency (0.80(9) %), and by measuring the phonon sideband, determined the zero-phonon emission fraction (16(1) %). Taken together, these parameters indicate that an integrated quantum optoelectronic platform based upon chalcogen donor qubits in silicon is well within reach of current capabilities.</description><identifier>EISSN: 2331-8422</identifier><identifier>DOI: 10.48550/arxiv.1809.10228</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Converters ; Dipole moments ; Donors (electronic) ; Energy gap ; Microwave photonics ; Optical communication ; Optoelectronics ; Phonons ; Physics - Applied Physics ; Physics - Quantum Physics ; Qubits (quantum computing) ; Silicon</subject><ispartof>arXiv.org, 2018-09</ispartof><rights>2018. 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We furthermore determined the optical excited state lifetime (7.7(4) ns), and therefore the natural radiative efficiency (0.80(9) %), and by measuring the phonon sideband, determined the zero-phonon emission fraction (16(1) %). 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subjects	Converters Dipole moments Donors (electronic) Energy gap Microwave photonics Optical communication Optoelectronics Phonons Physics - Applied Physics Physics - Quantum Physics Qubits (quantum computing) Silicon
title	Characterization of the Si:Se+ spin-photon interface
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