Erbium emitters in commercially fabricated nanophotonic silicon waveguides

Stephan Rinner; Florian Burger; Andreas Gritsch; Jonas Schmitt; Andreas Reiserer

doi:10.1515/nanoph-2023-0287

Erbium emitters in commercially fabricated nanophotonic silicon waveguides

Stephan Rinner, Florian Burger, Andreas Gritsch, Jonas Schmitt, Andreas Reiserer

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Quantum memories integrated into nanophotonic silicon devices are a promising platform for large quantum networks and scalable photonic quantum computers. In this context, erbium dopants are particularly attractive, as they combine optical transitions in the telecommunications frequency band with the potential for second-long coherence time. Here, we show that these emitters can be reliably integrated into commercially fabricated low-loss waveguides. We investigate several integration procedures and obtain ensembles of many emitters with an inhomogeneous broadening of <2 GHz and a homogeneous linewidth of <30 kHz. We further observe the splitting of the electronic spin states in a magnetic field up to 9 T that freezes paramagnetic impurities. Our findings are an important step toward long-lived quantum memories that can be fabricated on a wafer-scale using CMOS technology.

Original language	English
Pages (from-to)	3455-3462
Number of pages	8
Journal	Nanophotonics
Volume	12
Issue number	17
DOIs	https://doi.org/10.1515/nanoph-2023-0287
State	Published - 2 Aug 2023
Externally published	Yes

Keywords

quantum memory
quantum nanophotonics
quantum networks
quantum repeaters
rare-earth dopants
silicon photonics

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10.1515/nanoph-2023-0287

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abstract = "Quantum memories integrated into nanophotonic silicon devices are a promising platform for large quantum networks and scalable photonic quantum computers. In this context, erbium dopants are particularly attractive, as they combine optical transitions in the telecommunications frequency band with the potential for second-long coherence time. Here, we show that these emitters can be reliably integrated into commercially fabricated low-loss waveguides. We investigate several integration procedures and obtain ensembles of many emitters with an inhomogeneous broadening of <2 GHz and a homogeneous linewidth of <30 kHz. We further observe the splitting of the electronic spin states in a magnetic field up to 9 T that freezes paramagnetic impurities. Our findings are an important step toward long-lived quantum memories that can be fabricated on a wafer-scale using CMOS technology.",

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AU - Rinner, Stephan

AU - Burger, Florian

AU - Gritsch, Andreas

AU - Schmitt, Jonas

AU - Reiserer, Andreas

PY - 2023/8/2

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AB - Quantum memories integrated into nanophotonic silicon devices are a promising platform for large quantum networks and scalable photonic quantum computers. In this context, erbium dopants are particularly attractive, as they combine optical transitions in the telecommunications frequency band with the potential for second-long coherence time. Here, we show that these emitters can be reliably integrated into commercially fabricated low-loss waveguides. We investigate several integration procedures and obtain ensembles of many emitters with an inhomogeneous broadening of <2 GHz and a homogeneous linewidth of <30 kHz. We further observe the splitting of the electronic spin states in a magnetic field up to 9 T that freezes paramagnetic impurities. Our findings are an important step toward long-lived quantum memories that can be fabricated on a wafer-scale using CMOS technology.

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Erbium emitters in commercially fabricated nanophotonic silicon waveguides

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Keywords

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