Xiangming Li scite author profile

An artificial muscle capable of shape programmability, deformation-locking capacity without needing continuous external energy, and self-sensing capability is highly desirable yet challenging in applications of reconfigurable antenna, deployable space structures, etc. Inspired by coupled behavior of the muscles, bones, and nerve system of mammals, a multifunctional artificial muscle based on polydopamine-coated liquid crystal elastomer (LCE) and low–melting point alloy (LMPA) in the form of a concentric tube/rod is proposed. Thereinto, the outer LCE is used for reversible contraction and recovery (i.e., muscle function); the inner LMPA in the resolidification state is adopted for deformation locking, and that in the melt state is adopted for angle variation monitoring by detecting resistance change (i.e., bones and nerve functions, respectively). The proposed artificial muscle demonstrates multiple performances, including controllable bending angle, position, and direction; deformation locking for supporting heavy objects; and real-time monitoring of angle variation, which also provides a straightforward and effective approach for designing soft devices.

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High performance solid-state supercapacitors based on highly conductive organogel electrolyte at low temperature

Zheng

Yang

et al. 2022

Journal of Power Sources

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A flexible dual-function capacitive sensor enhanced by loop-patterned fibrous electrode and doped dielectric pillars for spatial perception

Luo

Chen

et al. 2023

Nano Res.

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Core–shell dry adhesives for rough surfaces via electrically responsive self-growing strategy

et al. 2022

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Bioinspired dry adhesives have an extraordinary impact in the field of robotic manipulation and locomotion. However, there is a considerable difference between artificial structures and biological ones regarding surface adaptability, especially for rough surfaces. This can be attributed to their distinct structural configuration and forming mechanism. Here, we propose a core–shell adhesive structure that is obtained through a growth strategy, i.e., an electrically responsive self-growing core–shell structure. This growth strategy results in a specific mushroom-shaped structure with a rigid core and a soft shell, which exhibits excellent adhesion on typical target surfaces with roughness ranging from the nanoscale to the microscale up to dozens of micrometers. The proposed adhesion strategy extends dry adhesives from smooth surfaces to rough ones, especially for rough surfaces with roughness up to dozens or hundreds of micrometers, opening an avenue for the development of dry adhesive-based devices and systems.

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Xiangming Li

Metal Micropatterning by Triboelectric Spark Discharge (Adv. Funct. Mater. 1/2022)

Shape-programmable, deformation-locking, and self-sensing artificial muscle based on liquid crystal elastomer and low–melting point alloy

High performance solid-state supercapacitors based on highly conductive organogel electrolyte at low temperature

A flexible dual-function capacitive sensor enhanced by loop-patterned fibrous electrode and doped dielectric pillars for spatial perception

Core–shell dry adhesives for rough surfaces via electrically responsive self-growing strategy

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