Nonlinear Quantum Photonics with a Tin-Vacancy Center Coupled to a One-Dimensional Diamond Waveguide

Matteo Pasini; Nina Codreanu; Tim Turan; Adrià Riera Moral; Christian F. Primavera; Lorenzo De Santis; Hans K.C. Beukers; Julia M. Brevoord; Christopher Waas; Johannes Borregaard; Ronald Hanson

doi:10.1103/PhysRevLett.133.023603

Nonlinear Quantum Photonics with a Tin-Vacancy Center Coupled to a One-Dimensional Diamond Waveguide

Matteo Pasini, Nina Codreanu, Tim Turan, Adrià Riera Moral, Christian F. Primavera, Lorenzo De Santis, Hans K.C. Beukers, Julia M. Brevoord, Christopher Waas, Johannes Borregaard, Ronald Hanson

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Abstract

Color centers integrated with nanophotonic devices have emerged as a compelling platform for quantum science and technology. Here, we integrate tin-vacancy centers in a diamond waveguide and investigate the interaction with light at the single-photon level in both reflection and transmission. We observe single-emitter-induced extinction of the transmitted light up to 25% and measure the nonlinear effect on the photon statistics. Furthermore, we demonstrate fully tunable interference between the reflected single-photon field and laser light backscattered at the fiber end and show the corresponding controlled change between bunched and antibunched photon statistics in the reflected field.

Original language	English
Article number	023603
Journal	Physical review letters
Volume	133
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.133.023603
Publication status	Published - 2024

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10.1103/PhysRevLett.133.023603

PhysRevLett.133.023603Final published version, 894 KBLicence: CC BY

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title = "Nonlinear Quantum Photonics with a Tin-Vacancy Center Coupled to a One-Dimensional Diamond Waveguide",

abstract = "Color centers integrated with nanophotonic devices have emerged as a compelling platform for quantum science and technology. Here, we integrate tin-vacancy centers in a diamond waveguide and investigate the interaction with light at the single-photon level in both reflection and transmission. We observe single-emitter-induced extinction of the transmitted light up to 25% and measure the nonlinear effect on the photon statistics. Furthermore, we demonstrate fully tunable interference between the reflected single-photon field and laser light backscattered at the fiber end and show the corresponding controlled change between bunched and antibunched photon statistics in the reflected field.",

author = "Matteo Pasini and Nina Codreanu and Tim Turan and {Riera Moral}, Adri{\`a} and Primavera, {Christian F.} and {De Santis}, Lorenzo and Beukers, {Hans K.C.} and Brevoord, {Julia M.} and Christopher Waas and Johannes Borregaard and Ronald Hanson",

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doi = "10.1103/PhysRevLett.133.023603",

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T1 - Nonlinear Quantum Photonics with a Tin-Vacancy Center Coupled to a One-Dimensional Diamond Waveguide

AU - Pasini, Matteo

AU - Codreanu, Nina

AU - Turan, Tim

AU - Riera Moral, Adrià

AU - Primavera, Christian F.

AU - De Santis, Lorenzo

AU - Beukers, Hans K.C.

AU - Brevoord, Julia M.

AU - Waas, Christopher

AU - Borregaard, Johannes

AU - Hanson, Ronald

PY - 2024

Y1 - 2024

N2 - Color centers integrated with nanophotonic devices have emerged as a compelling platform for quantum science and technology. Here, we integrate tin-vacancy centers in a diamond waveguide and investigate the interaction with light at the single-photon level in both reflection and transmission. We observe single-emitter-induced extinction of the transmitted light up to 25% and measure the nonlinear effect on the photon statistics. Furthermore, we demonstrate fully tunable interference between the reflected single-photon field and laser light backscattered at the fiber end and show the corresponding controlled change between bunched and antibunched photon statistics in the reflected field.

AB - Color centers integrated with nanophotonic devices have emerged as a compelling platform for quantum science and technology. Here, we integrate tin-vacancy centers in a diamond waveguide and investigate the interaction with light at the single-photon level in both reflection and transmission. We observe single-emitter-induced extinction of the transmitted light up to 25% and measure the nonlinear effect on the photon statistics. Furthermore, we demonstrate fully tunable interference between the reflected single-photon field and laser light backscattered at the fiber end and show the corresponding controlled change between bunched and antibunched photon statistics in the reflected field.

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DO - 10.1103/PhysRevLett.133.023603

M3 - Article

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VL - 133

JO - Physical review letters

JF - Physical review letters

IS - 2

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ER -

Nonlinear Quantum Photonics with a Tin-Vacancy Center Coupled to a One-Dimensional Diamond Waveguide

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