Manipulating multiple optical parametric processes in photonic topological insulators

Jiang, Zhen; Ji, Bo; Chen, Yanghe; Jiang, Chun; He, Guangqiang

doi:10.1103/PhysRevB.109.174110

Manipulating multiple optical parametric processes in photonic topological insulators

Jan 12, 2024

18 pages

Published in:

Phys.Rev.B 109 (2024) 17, 174110

Published: May 1, 2024

e-Print:

2401.06418 [physics.optics]

DOI:

10.1103/PhysRevB.109.174110 (publication)

View in:

ADS Abstract Service

pdf

reference search0 citations

Citations per year

0 Citations

Abstract: (APS)

Topological quantum optics has endowed integrated quantum devices with novel functionalities, including unidirectional transport and immunity to structural defects. Here we propose topological interfaces that support two distinct edge modes with different frequency ranges. The nonlinear four-wave mixing processes in the topological interfaces lead to the generation of signal and idler photons, each corresponding to distinct edge modes. By designing a diamondlike topological structure, we can couple the signal and idler photons into opposite branches, leading to spatial separation of the photon pairs. This behavior enables on-chip generation and flexible control of the topological biphoton states. More importantly, the biphoton states are inborn topologically protected, showing robustness against sharp bends and disorders. Our proposal offers the possibility of robust, multifunctional topological quantum devices, which may find applications in quantum information processing.

Note:

18pages, 12 figures

References(51)

Figures(7)

[1]

Chip-scale nonlinear photonics for quantum light generation

G. Moody
,
L. Chang
,
T.J. Steiner
,
J.E. Bowers

- AVS Quantum Sci. 2 (2020) 041702
•
DOI:
- 10.1116/5.0020684

[2]

Optical Quantum Computing

Jeremy L. O'Brien
(
- Bristol U.
)

- Science 318 (2007) 5856, 1567-1570
•
DOI:
- 10.1126/science.1142892

[3]

Integrated sources of photon quantum states based on nonlinear optics

Lucia Caspani
(
- Strathclyde U. and
- Heriot-Watt U. (main)
)
,
Chunle Xiong
(
- Sydney U.
)
,
Benjamin J. Eggleton
(
- Sydney U.
)
,
Daniele Bajoni
(
- Pavia U.
)
,
Marco Liscidini
(
- Pavia U.
)

et al.

- Light Sci. Appl. 6 (2017) 11, e17100
•
DOI:
- 10.1038/lsa.2017.100

[4]

Chip-based quantum key distribution

et al.

- Nature Commun. 8 (2017) 1, 13984
•
DOI:
- 10.1038/ncomms13984

[5]

Chip-integrated visible–telecom entangled photon pair source for quantum communication

X. Lu
,
Q. Li
,
D.A. Westly
,
G. Moille
,
A. Singh

et al.

- Nature Phys. 15 (2019) 373
•
DOI:
- 10.1038/s41567-018-0394-3

[6]

Recent advances on integrated quantum communications

A. Orieux
,
E. Diamanti

- J.Opt. 18 (2016) 083002
•
DOI:
- 10.1088/2040-8978/18/8/083002

[7]

Advances in photonic quantum sensing

S. Pirandola
(
- York U., England and
- MIT
)
,
B.R. Bardhan
(
- SUNY, Stony Brook
)
,
T. Gehring
(
- Denmark, Tech. U.
)
,
C. Weedbrook
(
- Xanadu Quant. Tech.
)
,
S. Lloyd
(
- MIT
)

- Nature Photon. 12 (2018) 12, 724-733
•
DOI:
- 10.1038/s41566-018-0301-6

[8]

Quantum sensing

- Rev.Mod.Phys. 89 (2017) 3, 035002,
- Rev.Mod.Phys. 89 (2017) 035002
•
e-Print:
- 1611.02427
•
DOI:
- 10.1103/RevModPhys.89.035002

[9]

Integrated photon-pair sources with nonlinear optics

- Appl.Phys.Rev. 8 (2021) 1, 011314
•
DOI:
- 10.1063/5.0030258

[10]

Quantum topological photonics

Q. Yan
,
X. Hu
,
Y. Fu
,
C. Lu
,
C. Fan

et al.

- Adv. Opt. Mater. 9 (2021) 2001739
•
DOI:
- 10.1002/adom.202001739

[11]

Topological metasurface: From passive toward active and beyond

J.W. You
,
Z. Lan
,
Q. Ma
,
Z. Gao
,
Y. Yang

et al.

- Photon. Res. 11 (2023) B65
•
DOI:
- 10.1364/PRJ.471905

[12]

A topological quantum optics interface

et al.

- Science 359 (2018) 6376, aaq0327
•
DOI:
- 10.1126/science.aaq0327

[13]

A topological source of quantum light

S. Mittal
,
E.A. Goldschmidt
,
M. Hafezi

- Nature 561 (2018) 502
•
DOI:
- 10.1038/s41586-018-0478-3

[14]

Tunable quantum interference using a topological source of indistinguishable photon pairs

S. Mittal
,
V.V. Orre
,
E.A. Goldschmidt
,
M. Hafezi

- Nature Photon. 15 (2021) 542
•
DOI:
- 10.1038/s41566-021-00810-1

[15]

Topologically protected valley-dependent quantum photonic circuits

Y. Chen
,
X.-T. He
,
Y.-J. Cheng
,
H.-Y. Qiu
,
L.-T. Feng

et al.

- Phys.Rev.Lett. 126 (2021) 230503
•
DOI:
- 10.1103/PhysRevLett.126.230503

[16]

Topological protection of continuous frequency entangled biphoton states

Z. Jiang
,
Y. Ding
,
C. Xi
,
G. He
,
C. Jiang

- Nanophoton. 10 (2021) 4019
•
DOI:
- 10.1515/nanoph-2021-0371

[17]

Topologically protected quantum entanglement emitters

T. Dai
,
Y. Ao
,
J. Bao
,
J. Mao
,
Y. Chi

et al.

- Nature Photon. 16 (2022) 248
•
DOI:
- 10.1038/s41566-021-00944-2

[18]

Enhanced Quantum Emission from a Topological Floquet Resonance

et al.

- PRX Quantum 5 (2024) 4, 040331
•
e-Print:
- 2308.11451
•
DOI:
- 10.1103/PRXQuantum.5.040331

[19]

Generation of quantum optical frequency combs in topological resonators

Z. Jiang
,
Y. Chen
,
C. Jiang
,
G. He

- Adv.Quantum Technol. 7 (2024) 2300354
•
DOI:
- 10.1002/qute.202300354

[20]

On-chip topological transport of optical frequency combs in silicon-based valley photonic crystals

et al.

e-Print:
- 2310.15629

[21]

Four-wave mixing of topological edge plasmons in graphene metasurfaces

J.W. You
,
Z. Lan
,
N.C. Panoiu

- Sci.Adv. 6 (2020) eaaz3910
•
DOI:
- 10.1126/sciadv.aaz3910

[22]

Third-harmonic generation in photonic topological metasurfaces

D. Smirnova
,
S. Kruk
,
D. Leykam
,
E. Melik-Gaykazyan
,
D.-Y. Choi

et al.

- Phys.Rev.Lett. 123 (2019) 103901
•
DOI:
- 10.1103/PhysRevLett.123.103901

[23]

Non-hermitian topological phase transitions controlled by nonlinearity

T. Dai
,
Y. Ao
,
J. Mao
,
Y. Yang
,
Y. Zheng

et al.

- Nature Phys. 20 (2023) 101
•
DOI:
- 10.1038/s41567-023-02244-8

[24]

Nonlinear topological photonics

D. Smirnova
,
D. Leykam
,
Y. Chong
,
Y. Kivshar

- Appl.Phys.Rev. 7 (2020) 021306
•
DOI:
- 10.1063/1.5142397

[25]

Topological dissipative Kerr soliton combs in a valley photonic crystal resonator

Z. Jiang
,
L. Zhou
,
W. Li
,
Y. Li
,
L. Feng

et al.

- Phys.Rev.B 108 (2023) 205421
•
DOI:
- 10.1103/PhysRevB.108.205421

1-25 of 51
1
2
3
25 / page