Donglei Chen scite author profile

Donglei Chen

5Publications

2Citation Statements Received

60Citation Statements Given

How they've been cited

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148

Affiliations

China General Nuclear Power Corporation (China), City University of Hong Kong

Publications

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In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever

et al. 2023

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Current state‐of‐the‐art in situ transmission electron microscopy (TEM) characterization technology has been capable of statically or dynamically nanorobotic manipulating specimens, affording abundant atom‐level material attributes. However, an insurmountable barrier between material attributes investigations and device‐level application explorations exists due to immature in situ TEM manufacturing technology and sufficient external coupled stimulus. These limitations seriously prevent the development of in situ device‐level TEM characterization. Herein, a representative in situ opto‐electromechanical TEM characterization platform is put forward by integrating an ultra‐flexible micro‐cantilever chip with optical, mechanical, and electrical coupling fields for the first time. On this platform, static and dynamic in situ device‐level TEM characterizations are implemented by utilizing molybdenum disulfide (MoS2) nanoflake as channel material. E‐beam modulation behavior in MoS2 transistors is demonstrated at ultra‐high e‐beam acceleration voltage (300 kV), stemming from inelastic scattering electron doping into MoS2 nanoflakes. Moreover, in situ dynamic bending MoS2 nanodevices without/with laser irradiation reveals asymmetric piezoresistive properties based on electromechanical effects and secondary enhanced photocurrent based on opto‐electromechanical coupling effects, accompanied by real‐time monitoring atom‐level characterization. This approach provides a step toward advanced in situ device‐level TEM characterization technology with excellent perception ability and inspires in situ TEM characterization with ultra‐sensitive force feedback and light sensing.

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In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever (Adv. Mater. 28/2023)

et al. 2023

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TEM Cantilever Chips In article number 2301439, Chaojian Hou, Jing Zhao, Lixin Dong, and co‐workers report a cantilever chip for in situ transmission electron microscopy (TEM). The chip consists of a MoS2 opto‐electromechanical sensor and a plasmonic antenna array built on the top of a Si3N4 cantilever, forming an electron‐beam‐transparent (thickness ≈100 nm) nano‐opto‐electromechanical system (NOEMS), enabling the in situ calibration/characterization of the NOEMS sensor or another device, with the NOEMS serving as a sensor to correlate the physical properties and atomic structures.

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A Hybrid Nanorobotic Manipulation Platform: A Sharing Holder between a Cs-TEM and an SEM for Micro to Sub-nanometer Fabrication

Zhang

Chen

Hou

et al. 2022

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Growth of CdZnTe (2 1 1) epilayers on GaAs by close spaced sublimation as an alternative substrate for HgCdTe growth

Zha

Cao

et al. 2023

Infrared Physics & Technology

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An SEM-TEM Joint Nanorobotic Manipulation System for Extreme Manufacturing

Zhang

Chen

Hou

et al. 2023

IEEE Trans. Nanotechnology

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Donglei Chen

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever (Adv. Mater. 28/2023)

A Hybrid Nanorobotic Manipulation Platform: A Sharing Holder between a Cs-TEM and an SEM for Micro to Sub-nanometer Fabrication

Growth of CdZnTe (2 1 1) epilayers on GaAs by close spaced sublimation as an alternative substrate for HgCdTe growth

An SEM-TEM Joint Nanorobotic Manipulation System for Extreme Manufacturing

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Donglei Chen

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS2 Micro‐Cantilever

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS2 Micro‐Cantilever (Adv. Mater. 28/2023)

A Hybrid Nanorobotic Manipulation Platform: A Sharing Holder between a Cs-TEM and an SEM for Micro to Sub-nanometer Fabrication

Growth of CdZnTe (2 1 1) epilayers on GaAs by close spaced sublimation as an alternative substrate for HgCdTe growth

An SEM-TEM Joint Nanorobotic Manipulation System for Extreme Manufacturing

Contact Info

Product

Resources

About

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever

In Situ Device‐Level TEM Characterization Based on Ultra‐Flexible Multilayer MoS₂ Micro‐Cantilever (Adv. Mater. 28/2023)