X. S. Shen scite author profile

X. S. Shen

2Publications

21Citation Statements Received

91Citation Statements Given

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Affiliations

University of California, Merced, Fudan University

Publications

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Raman scattering in InAs nanowires synthesized by a solvothermal route

Wei

et al. 2006

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Micro-Raman scattering experiment has been performed to study solvothermally synthesized InAs nanowires with different diameters. Strong low frequency branch of the LO-phonon-plasmon mode (L−) was observed. The longitudinal optic (LO) mode was found to be dependent on diameter of the nanowires. The wave vector uncertainty and the carrier concentration related Fermi-Thomas screening effect were proposed to play important roles for this phenomenon. Laser heating, phonon confinement, surface defects, together with the diameter distribution effects were also discussed.

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Directional, Low‐Energy Driven Thermal Actuating Bilayer Enabled by Coordinated Submolecular Switching

Leveille

Shen

et al. 2021

Advanced Science

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The authors reveal a thermal actuating bilayer that undergoes reversible deformation in response to low-energy thermal stimuli, for example, a few degrees of temperature increase. It is made of an aligned carbon nanotube (CNT) sheet covalently connected to a polymer layer in which dibenzocycloocta-1,5-diene (DBCOD) actuating units are oriented parallel to CNTs. Upon exposure to low-energy thermal stimulation, coordinated submolecular-level conformational changes of DBCODs result in macroscopic thermal contraction. This unique thermal contraction offers distinct advantages. It's inherently fast, repeatable, low-energy driven, and medium independent. The covalent interface and reversible nature of the conformational change bestow this bilayer with excellent repeatability, up to at least 70 000 cycles. Unlike conventional CNT bilayer systems, this system can achieve high precision actuation readily and can be scaled down to nanoscale. A new platform made of poly(vinylidene fluoride) (PVDF) in tandem with the bilayer can harvest low-grade thermal energy and convert it into electricity. The platform produces 86 times greater energy than PVDF alone upon exposure to 6 °C thermal fluctuations above room temperature. This platform provides a pathway to low-grade thermal energy harvesting. It also enables low-energy driven thermal artificial robotics, ultrasensitive thermal sensors, and remote controlled near infrared (NIR) driven actuators.

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X. S. Shen

Raman scattering in InAs nanowires synthesized by a solvothermal route

Directional, Low‐Energy Driven Thermal Actuating Bilayer Enabled by Coordinated Submolecular Switching

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