Hongya Wu scite author profile

Hongya Wu

3Publications

48Citation Statements Received

102Citation Statements Given

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113

Affiliations

Collaborative Innovation Center of Advanced Microstructures, Nanjing University

Publications

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On-Chip Optical Nonreciprocity Using an Active Microcavity

Jiang

Yang

et al. 2016

Sci Rep

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Optically nonreciprocal devices provide critical functionalities such as light isolation and circulation in integrated photonic circuits for optical communications and information processing, but have been difficult to achieve. By exploring gain-saturation nonlinearity, we demonstrate on-chip optical nonreciprocity with excellent isolation performance within telecommunication wavelengths using only one toroid microcavity. Compatible with current complementary metal-oxide-semiconductor process, our compact and simple scheme works for a very wide range of input power levels from ~10 microwatts down to ~10 nanowatts, and exhibits remarkable properties of one-way light transport with sufficiently low insertion loss. These superior features make our device become a promising critical building block indispensable for future integrated nanophotonic networks.

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High-Q silica microdisk optical resonators with large wedge angles on a silicon chip

Li¹,

Liu²,

Jiang³

et al. 2015

Photon. Res.

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Modeling of On-Chip Optical Nonreciprocity with an Active Microcavity

et al. 2015

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On-chip nonreciprocal light transport holds a great impact on optical information processing and communications based upon integrated photonic devices. By harvesting gain-saturation nonlinearity, we recently demonstrated on-chip optical asymmetric transmission at telecommunication bands with superior nonreciprocal performances using only one active whispering-gallery-mode microtoroid resonator, beyond the commonly adopted magneto-optical (Faraday) effect. Here, detailed theoretical analysis is presented with respect to the reported scheme. Despite the fact that our model is simply the standard coupled-mode theory, it agrees well with the experiment and describes the essential one-way light transport in this nonreciprocal device. Further discussions, including the connection with the second law of thermodynamics and Fano resonance, are also briefly made in the end.

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Hongya Wu

On-Chip Optical Nonreciprocity Using an Active Microcavity

High-Q silica microdisk optical resonators with large wedge angles on a silicon chip

Modeling of On-Chip Optical Nonreciprocity with an Active Microcavity

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