Controlling coherence between waveguide-coupled quantum dots

D. Hallett; J. Wiercinski; L. Hallacy; S. Sheldon; R. Dost; N. Martin; A. Fenzl; I. Farrer; A. K. Verma; M. Cygorek; E. M. Gauger; M. S. Skolnick; L. R. Wilson

doi:10.1103/1xsb-bf5r

Controlling coherence between waveguide-coupled quantum dots

D. Hallett
, J. Wiercinski
, L. Hallacy
, S. Sheldon
, R. Dost
, N. Martin
, A. Fenzl
, I. Farrer
, A. K. Verma
, M. Cygorek
, E. M. Gauger
, M. S. Skolnick
, L. R. Wilson

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

1 Citation (Scopus)

1 Downloads (Pure)

Abstract

We present a waveguide design incorporating a split-diode structure, allowing independent electrical control of transition energies of multiple emitters over a wide range with minimal loss in waveguide coupling efficiency. We use this design to systematically map out the transition from superradiant to independent emission from two quantum dots through control of the emitter detuning. We perform both lifetime and Hanbury Brown-Twiss measurements on the device, observing antidips in the photon coincidences—indicating collective emission, while at the same time observing a drop in lifetime around zero detuning—indicating superradiant behavior. Performing both measurements allows us to investigate detuning regions, which show both superradiant rate enhancement and interemitter coherence, as well as regions in which correlations persist in the absence of rate enhancement.

Original language	English
Article number	L021003
Journal	Physical Review Applied
Volume	25
Issue number	2
Early online date	17 Feb 2026
DOIs	https://doi.org/10.1103/1xsb-bf5r
Publication status	Published - Feb 2026

Keywords

Electro-optic effects
Nanophotonics
Optical coherence
Quantum entanglement
Semiconductor quantum optics
Superradiance & subradiance
Double quantum dots
III-V semiconductors

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title = "Controlling coherence between waveguide-coupled quantum dots",

abstract = "We present a waveguide design incorporating a split-diode structure, allowing independent electrical control of transition energies of multiple emitters over a wide range with minimal loss in waveguide coupling efficiency. We use this design to systematically map out the transition from superradiant to independent emission from two quantum dots through control of the emitter detuning. We perform both lifetime and Hanbury Brown-Twiss measurements on the device, observing antidips in the photon coincidences—indicating collective emission, while at the same time observing a drop in lifetime around zero detuning—indicating superradiant behavior. Performing both measurements allows us to investigate detuning regions, which show both superradiant rate enhancement and interemitter coherence, as well as regions in which correlations persist in the absence of rate enhancement.",

keywords = "Electro-optic effects, Nanophotonics, Optical coherence, Quantum entanglement, Semiconductor quantum optics, Superradiance \& subradiance, Double quantum dots, III-V semiconductors",

author = "D. Hallett and J. Wiercinski and L. Hallacy and S. Sheldon and R. Dost and N. Martin and A. Fenzl and I. Farrer and Verma, \{A. K.\} and M. Cygorek and Gauger, \{E. M.\} and Skolnick, \{M. S.\} and Wilson, \{L. R.\}",

note = "Publisher Copyright: {\textcopyright} 2026 authors. Published by the American Physical Society.",

year = "2026",

month = feb,

doi = "10.1103/1xsb-bf5r",

language = "English",

volume = "25",

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AU - Hallett, D.

AU - Wiercinski, J.

AU - Hallacy, L.

AU - Sheldon, S.

AU - Dost, R.

AU - Martin, N.

AU - Fenzl, A.

AU - Farrer, I.

AU - Verma, A. K.

AU - Cygorek, M.

AU - Gauger, E. M.

AU - Skolnick, M. S.

AU - Wilson, L. R.

PY - 2026/2

Y1 - 2026/2

N2 - We present a waveguide design incorporating a split-diode structure, allowing independent electrical control of transition energies of multiple emitters over a wide range with minimal loss in waveguide coupling efficiency. We use this design to systematically map out the transition from superradiant to independent emission from two quantum dots through control of the emitter detuning. We perform both lifetime and Hanbury Brown-Twiss measurements on the device, observing antidips in the photon coincidences—indicating collective emission, while at the same time observing a drop in lifetime around zero detuning—indicating superradiant behavior. Performing both measurements allows us to investigate detuning regions, which show both superradiant rate enhancement and interemitter coherence, as well as regions in which correlations persist in the absence of rate enhancement.

AB - We present a waveguide design incorporating a split-diode structure, allowing independent electrical control of transition energies of multiple emitters over a wide range with minimal loss in waveguide coupling efficiency. We use this design to systematically map out the transition from superradiant to independent emission from two quantum dots through control of the emitter detuning. We perform both lifetime and Hanbury Brown-Twiss measurements on the device, observing antidips in the photon coincidences—indicating collective emission, while at the same time observing a drop in lifetime around zero detuning—indicating superradiant behavior. Performing both measurements allows us to investigate detuning regions, which show both superradiant rate enhancement and interemitter coherence, as well as regions in which correlations persist in the absence of rate enhancement.

KW - Electro-optic effects

KW - Nanophotonics

KW - Optical coherence

KW - Quantum entanglement

KW - Semiconductor quantum optics

KW - Superradiance & subradiance

KW - Double quantum dots

KW - III-V semiconductors

UR - https://www.scopus.com/pages/publications/105030548479

U2 - 10.1103/1xsb-bf5r

DO - 10.1103/1xsb-bf5r

M3 - Article

SN - 2331-7019

VL - 25

JO - Physical Review Applied

JF - Physical Review Applied

IS - 2

M1 - L021003

ER -

Controlling coherence between waveguide-coupled quantum dots

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