C
Chang-Ling Zou
Researcher at University of Science and Technology of China
Publications - 355
Citations - 12194
Chang-Ling Zou is an academic researcher from University of Science and Technology of China. The author has contributed to research in topics: Photonics & Resonator. The author has an hindex of 48, co-authored 314 publications receiving 8627 citations. Previous affiliations of Chang-Ling Zou include Nanjing University & Yale University.
Papers
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Journal ArticleDOI
Phase sensitive imaging of 10 GHz vibrations in an AlN microdisk resonator
TL;DR: A high frequency phase-sensitive heterodyne vibrometer, operating up to 10 GHz, which will be of great significance for the development of high frequency mechanical devices.
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Non-Hermitian Magnon-Photon Interference in an Atomic Ensemble.
Rong Wen,Chang-Ling Zou,Xinyu Zhu,Peng Chen,Z. Y. Ou,Jiefei Chen,Jiefei Chen,Weiping Zhang,Weiping Zhang +8 more
TL;DR: In this article, a tunable non-Hermitian lossy beam splitter for the interference between traveling photonic and localized magnonic modes is presented. But the authors focus on the non-hermiticity of photonic devices and do not consider the effect of the photon and magnon modes on the beamforming process.
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Dissipative sensing with low detection limit in a self-interference microring resonator
TL;DR: In this paper, a dissipative sensing scheme based on a self-interference microring resonator (SIMRR), which is robust against lasing and microcavity frequency noise in the detecting system with a low noise level, is systematically investigated.
Journal ArticleDOI
Transient microcavity sensor.
TL;DR: A transient and high sensitivity sensor based on high-Q microcavity is proposed and studied theoretically and it's demonstrated that the transient sensor can sense coupling region, external linear variation together with the speed and the size of a nanoparticle.
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Control of second-harmonic generation in doubly resonant aluminum nitride microrings to address a rubidium two-photon clock transition.
TL;DR: The phase-matching window and resonance wavelength with respect to varying microring widths, radii, and temperatures is analyzed and can be generalized to any target pump wavelength in the telecom band with picometer precision.