Chengyun Wang scite author profile

Chengyun Wang

5Publications

21Citation Statements Received

48Citation Statements Given

How they've been cited

How they cite others

224

Affiliations

Guangxi University, Dongguan University of Technology

Publications

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3D printing of dual cross-linked hydrogel for fingerprint-like iontronic pressure sensor

Yan

Zhou

Wang

et al. 2021

Smart Mater. Struct.

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Hydrogels with intrinsic high stretchability and flexibility are extremely attractive for soft electronics. However, the existing complicated and laborious methods (such as mold curing) to fabricate microstructured hydrogel (MH) still limit the development of hydrogel-based sensors for flexible devices. Herein, we use digital light processing 3D printing technology to rapidly construct double-network (DN) ionic conductive hydrogel, and then design and print fingerprint-like MH film to manufacture an iontronic pressure sensor. In particular, the DN hydrogel consists of acrylamide/acrylic acid to form a covalently cross-linked network, and magnesium chloride is introduced to form an ionic cross-linked physical network in the hydrogel. The printability (with resolution 150 μm) and mechanical property tunability of DN hydrogel enable the convenient fabrication of sensors. With the biomimetic fingerprint MH film, the iontronic pressure sensor not only has a high sensitivity (0.06 kPa−1), but also has a large detection range (26 Pa–70 kPa) and good stability (200 cycles of pressure loading). We demonstrated that our sensor can be applied to realize tactile sensing in a prosthetic application and detect human motion. With the easy strategy of constructing DN hydrogel with microstructures by 3D printing technology, hydrogel-based sensors are anticipated to be employed in more smart electronics.

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3D printing highly stretchable conductors for flexible electronics with low signal hysteresis

Zhou

Yan

Wang

et al. 2021

Virtual and Physical Prototyping

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Effect of picosecond laser texturing on the friction behavior of silicon carbide in hybrid ceramic bearings under dry and water lubrication

Chen

Wang

Jiang

et al. 2023

Ceramics International

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Optimized sintering strategy for lunar regolith simulant particles bound via vat photopolymerization

Wang

Gong

et al. 2023

Materials Chemistry and Physics

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Vat photopolymerization of low-titanium lunar regolith simulant for optimal mechanical performance

Wang

Gong

Wei

et al. 2022

Ceramics International

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Chengyun Wang

3D printing of dual cross-linked hydrogel for fingerprint-like iontronic pressure sensor

3D printing highly stretchable conductors for flexible electronics with low signal hysteresis

Effect of picosecond laser texturing on the friction behavior of silicon carbide in hybrid ceramic bearings under dry and water lubrication

Optimized sintering strategy for lunar regolith simulant particles bound via vat photopolymerization

Vat photopolymerization of low-titanium lunar regolith simulant for optimal mechanical performance

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