Controlled-phase gate by dynamic coupling of photons to a two-level emitter

Stefan Krastanov; Kurt Jacobs; Gerald Gilbert; Dirk R. Englund; Mikkel Heuck

doi:10.1038/s41534-022-00604-5

Controlled-phase gate by dynamic coupling of photons to a two-level emitter

Stefan Krastanov^*, Kurt Jacobs, Gerald Gilbert, Dirk R. Englund, Mikkel Heuck

^*Corresponding author for this work

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Abstract

We propose an architecture for achieving high-fidelity deterministic quantum logic gates on dual-rail encoded photonic qubits by letting photons interact with a two-level emitter (TLE) inside an optical cavity. The photon wave packets that define the qubit are preserved after the interaction due to a quantum control process that actively loads and unloads the photons from the cavity and dynamically alters their effective coupling to the TLE. The controls rely on nonlinear wave mixing between cavity modes enhanced by strong externally modulated electromagnetic fields or on AC Stark shifts of the TLE transition energy. We numerically investigate the effect of imperfections in terms of loss and dephasing of the TLE as well as control field miscalibration. Our results suggest that III-V quantum dots in GaAs membranes is a promising platform for photonic quantum information processing.

Original language	English
Article number	103
Journal	npj Quantum Information
Volume	8
Number of pages	9
ISSN	2056-6387
DOIs	https://doi.org/10.1038/s41534-022-00604-5
Publication status	Published - Dec 2022

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title = "Controlled-phase gate by dynamic coupling of photons to a two-level emitter",

abstract = "We propose an architecture for achieving high-fidelity deterministic quantum logic gates on dual-rail encoded photonic qubits by letting photons interact with a two-level emitter (TLE) inside an optical cavity. The photon wave packets that define the qubit are preserved after the interaction due to a quantum control process that actively loads and unloads the photons from the cavity and dynamically alters their effective coupling to the TLE. The controls rely on nonlinear wave mixing between cavity modes enhanced by strong externally modulated electromagnetic fields or on AC Stark shifts of the TLE transition energy. We numerically investigate the effect of imperfections in terms of loss and dephasing of the TLE as well as control field miscalibration. Our results suggest that III-V quantum dots in GaAs membranes is a promising platform for photonic quantum information processing.",

author = "Stefan Krastanov and Kurt Jacobs and Gerald Gilbert and Englund, {Dirk R.} and Mikkel Heuck",

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AU - Krastanov, Stefan

AU - Jacobs, Kurt

AU - Gilbert, Gerald

AU - Englund, Dirk R.

AU - Heuck, Mikkel

PY - 2022/12

Y1 - 2022/12

N2 - We propose an architecture for achieving high-fidelity deterministic quantum logic gates on dual-rail encoded photonic qubits by letting photons interact with a two-level emitter (TLE) inside an optical cavity. The photon wave packets that define the qubit are preserved after the interaction due to a quantum control process that actively loads and unloads the photons from the cavity and dynamically alters their effective coupling to the TLE. The controls rely on nonlinear wave mixing between cavity modes enhanced by strong externally modulated electromagnetic fields or on AC Stark shifts of the TLE transition energy. We numerically investigate the effect of imperfections in terms of loss and dephasing of the TLE as well as control field miscalibration. Our results suggest that III-V quantum dots in GaAs membranes is a promising platform for photonic quantum information processing.

AB - We propose an architecture for achieving high-fidelity deterministic quantum logic gates on dual-rail encoded photonic qubits by letting photons interact with a two-level emitter (TLE) inside an optical cavity. The photon wave packets that define the qubit are preserved after the interaction due to a quantum control process that actively loads and unloads the photons from the cavity and dynamically alters their effective coupling to the TLE. The controls rely on nonlinear wave mixing between cavity modes enhanced by strong externally modulated electromagnetic fields or on AC Stark shifts of the TLE transition energy. We numerically investigate the effect of imperfections in terms of loss and dephasing of the TLE as well as control field miscalibration. Our results suggest that III-V quantum dots in GaAs membranes is a promising platform for photonic quantum information processing.

U2 - 10.1038/s41534-022-00604-5

DO - 10.1038/s41534-022-00604-5

M3 - Journal article

AN - SCOPUS:85137766655

SN - 2056-6387

VL - 8

JO - npj Quantum Information

JF - npj Quantum Information

M1 - 103

ER -

Controlled-phase gate by dynamic coupling of photons to a two-level emitter

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