Inverse design in quantum nanophotonics: combining local-density-of-states and deep learning

Recent advances in inverse-design approaches for discovering optical structures based on desired functional characteristics have reshaped the landscape of nanophotonic structures, where most studies have focused on how light interacts with nanophotonic structures only. When quantum emitters (QEs), s...

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Bibliographic Details
Published in:Nanophotonics (Berlin, Germany) Germany), 2023-05, Vol.12 (11), p.1943-1955
Main Authors: Liu, Guang-Xin, Liu, Jing-Feng, Zhou, Wen-Jie, Li, Ling-Yan, You, Chun-Lian, Qiu, Cheng-Wei, Wu, Lin
Format: Article
Language:English
Subjects:
Bridges
Deep learning
Density of states
Design optimization
Emitters
entanglement dynamics
Generalized inverse
Inverse design
local density of states
Multilayers
Nanoparticles
nanophotonics
Neural networks
Quantum dots
Quantum entanglement
Quantum optics
Spontaneous emission
spontaneous emission dynamics
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Summary:Recent advances in inverse-design approaches for discovering optical structures based on desired functional characteristics have reshaped the landscape of nanophotonic structures, where most studies have focused on how light interacts with nanophotonic structures only. When quantum emitters (QEs), such as atoms, molecules, and quantum dots, are introduced to couple to the nanophotonic structures, the light–matter interactions become much more complicated, forming a rapidly developing field – quantum nanophotonics. Typical quantum functional characteristics depend on the intrinsic properties of the QE and its electromagnetic environment created by the nanophotonic structures, commonly represented by a scalar quantity, local-density-of-states (LDOS). In this work, we introduce a generalized inverse-design framework in quantum nanophotonics by taking LDOS as the bridge to connect the nanophotonic structures and the quantum functional characteristics. We take a simple system consisting of QEs sitting on a single multilayer shell–metal–nanoparticle (SMNP) as an example, apply fully-connected neural networks to model the LDOS of SMNP, inversely design and optimize the geometry of the SMNP based on LDOS, and realize desirable quantum characteristics in two quantum nanophotonic problems: spontaneous emission and entanglement. Our work introduces deep learning to the quantum optics domain for advancing quantum device designs; and provides a new platform for practicing deep learning to design nanophotonic structures for complex problems without a direct link between structures and functional characteristics.
ISSN:2192-8606
2192-8614
2192-8614
DOI:10.1515/nanoph-2022-0746