3D Chiral Micro‐Pinwheels Based on Rolling‐Up Kirigami Technology

Wang, Kun; Hou, Chaojian; Cong, Longqing; Zhang, Wenqi; Fan, Lu; Wang, Xiaokai; Dong, Lixin

doi:10.1002/smtd.202201627

Cited by 8 publications

(1 citation statement)

References 54 publications

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“…Based on the above basic theory, we designed the windmill fog collector inspired by the beetles and the Origami windmill. − First, a semicircular bulge of 2 mm in diameter is pressed on the square surface by a mold, and then, nanoalumina is grown on the surface by anodizing to obtain a superhydrophilic surface. Then, stearic acid is used to locally modify the surface to a superhydrophobic surface.…”

Section: Resultsmentioning

confidence: 99%

Superhydrophobic Bulgy Windmill for Synchronous Efficient Fog Collection and Power Generation

Li,

Wang,

Xin

et al. 2024

ACS Appl. Mater. Interfaces

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The shortage of freshwater resources is a serious problem faced by mankind in the 21st century. To maximize the acquisition of freshwater resources, numerous fog collectors have been constructed. In the process of fog collection accompanied by the movement of the wind, the mechanical energy brought about by the wind is often ignored. Based on this, inspired by beetles and origami art, we designed a windmill installation with a bump on the edge. Droplets nucleate at the windmill bulge and accelerate the transport process under the action of centrifugal force. This leads to quick fog collection and reduces the secondary evaporation rate of freshwater resources. The fog collection efficiency can reach 2.8 times that of the original sample. Moreover, the windmill can convert mechanical energy into electricity while collecting fog, and the operating voltage of a single windmill can reach 0.85 V. After the array, the amount of fog collected by the windmill and the power generation voltage can be increased by multiple times, which realizes the efficient use of energy and provides a new idea for the design of an efficient fog collector in the future.

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Section: Resultsmentioning

confidence: 99%

Superhydrophobic Bulgy Windmill for Synchronous Efficient Fog Collection and Power Generation

Li,

Wang,

Xin

et al. 2024

ACS Appl. Mater. Interfaces

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Laser‐Guided Self‐Assembly of Thin Films into Micro‐Rolls

Chen,

Tan,

Yang

et al. 2024

Adv Funct Materials

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Advanced manufacturing techniques offer tremendous potential in electronics, photonics, and biomedicine. Self‐assembly is a powerful strategy for creating three‐dimensional (3D) artificial structures, but existing thin film release techniques have limitations in the relatively complex processes. Herein, a localized laser scribing strategy is proposed to guide the self‐assembly of two‐dimensional thin films into 3D microstructures. It is revealed that laser‐induced heating and momentum can release thin films and roll them into various microstructures. Uniquely, this method allows accurate control of shapes, curvatures, orientations, and sizes for the fabricated rolls. This is a one‐step strategy with no pre‐patterning or post‐drying required. The proposed method represents a significant improvement over existing self‐assembly techniques and may enrich the thin film self‐assembly materials and applications. As proof of concept, the prepared gold micro‐rolls are demonstrated as implanted stents in porcine arteries with impressive flexibility. This study provides a new approach to creating 3D microstructures with simplicity and high repeatability and has significant implications for the future of advanced manufacturing, especially in emerging miniaturized applications, such as invasive robotics, minimized drug delivery, implanted batteries, and nanophotonics.

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On‐Chip THz Helical Antenna Based on Metal Self‐Rolled‐up Membrane Nanotechnology

Li,

He,

Zhou

et al. 2024

Adv Materials Technologies

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This paper demonstrates the on‐chip terahertz (THz) helical antenna based on metal self‐rolled‐up membrane (M‐SRuM) nanotechnology, which utilizes the residual stress in multilayer metal membrane deposited by electron beam (E‐beam) evaporation to provide the rolling force and to form the radiation body of the helical antenna. Precise design method is proposed based on multi‐physics modeling for mechanical and electrical analysis, and the two operating modes of on‐chip helical antenna are modeled and analyzed. The test results show that the normal mode of self‐rolled‐up THz helical antenna is able to operate at frequency as high as 0.223 THz with the corresponding impedance bandwidth of 13 GHz.

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3D Chiral Micro‐Pinwheels Based on Rolling‐Up Kirigami Technology

Cited by 8 publications

References 54 publications

Superhydrophobic Bulgy Windmill for Synchronous Efficient Fog Collection and Power Generation

Superhydrophobic Bulgy Windmill for Synchronous Efficient Fog Collection and Power Generation

Laser‐Guided Self‐Assembly of Thin Films into Micro‐Rolls

On‐Chip THz Helical Antenna Based on Metal Self‐Rolled‐up Membrane Nanotechnology

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