Research

Multi-dimensional Optical Microscopy

This division is committed to developing multi-dimensional spectral microscopy, as well as the optical analysis of micro-nano structures and their opto electronic devices. The research fields mainly include near-field spectroscopy and microscopy, micro-opto electronic devices, ultra fast dynamics of low-dimensional materials, and low-temperature photo-physics.

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Team

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Zhou Zhou

2017 PhD Candidate

Near-field optics and microscopy in low-dimensional materials

Zhichen Zhao

2020 PhD Candidate

Near-field optics and microscopy in low-dimensional materials

Naxi Liu

2020 Master Student

Photoelectric response of two-dimensional materials

Renkang Song

2021 PhD Candidate

Micro-optics in two-dimensional optoelectronic devices

Chenyu Wan

2021 Master Student

Micro-optics in two-dimensional materials

Lei Zhou

2022 PhD Candidate

Nano-optics in two-dimensional materials

Anhang Liu

2022 PhD Candidate

Nonlinear optics in two-dimensional materials

Ke Yu

2022 Master Student

Micro-optics in two-dimensional materials

Yanzhen Yin

2022 Master Student

Low-temperature micro-optics in two-dimensional materials

Linyuan Dou

2022 PhD Candidate

On-chip metasurface design and numerical simulation

Shenao Zhao

2023 PhD candidate

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Xiangkun Zeng

2023 PhD Candidate

Yu Yin

2023 Master student

Nonlinear optics of low-dimension materials

Zerui Wang

2023 Master Student

Near-field optical techniques to study micro- and nanostructures and low-dimens ional materials

Zeying Fan

Undergraduate

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Han Zhang

Undergraduate

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Research Infrastructure

In this division, by combining confocal microscopy with infrared scanning near-field microscope, the optical diffraction limit has been exceeded, obtaining a high spatial resolution. In the time dimension, through 2–14 μm femtosecond or picosecond lasers and a 500–5000 nm femtosecond laser, along with a pump-probe technique and coherent multi-dimensional spectroscopy, the time resolution of low-dimensional materials and their optoelectronic devices has been obtained. In the energy dimension, the photon energy in a large range has been examined using a grating spectrometer and a Mercury Cadmium Telluride (MCT) detector based on Fourier-transform infrared (FTIR) spectroscopy. With such an infrastructure, research in spectral microscopy, ultrafast spectroscopy, and temp-spatial resolution can be conducted.

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