Laser‐Induced Graphene for Electrothermally Controlled, Mechanically Guided, 3D Assembly and Human–Soft Actuators Interaction

Ling, Yun; Pang, Wenbo; Li, Xiaopeng; Goswami, Shivam; Xu, Zheng; Stroman, David W.; Liu, Yachao; Fei, Qihui; Xu, Yadong; Zhao, Ganggang; Sun, Bohan; Xie, Jingwei; Huang, Guoliang; Zhang, Yihui; Yan, Zheng

doi:10.1002/adma.201908475

Cited by 137 publications

(147 citation statements)

References 54 publications

(62 reference statements)

Supporting

Mentioning

142

Contrasting

Order By: Relevance

“…MRSM with reprogrammable magnetic anisotropies have a wide spectrum of applications. First, they are compatible with the recently demonstrated responsive buckling assembly for fabrication of 3D architectures 35 – 37 . To fabricate them, passive 2D films are selectively bonded onto the responsive substrates.…”

Section: Resultsmentioning

confidence: 71%

Laser reprogramming magnetic anisotropy in soft composites for reconfigurable 3D shaping

et al. 2020

Self Cite

View full text Add to dashboard Cite

Responsive soft materials capable of exhibiting various three-dimensional (3D) shapes under the same stimulus are desirable for promising applications including adaptive and reconfigurable soft robots. Here, we report a laser rewritable magnetic composite film, whose responsive shape-morphing behaviors induced by a magnetic field can be digitally and repeatedly reprogrammed by a facile method of direct laser writing. The composite film is made from an elastomer and magnetic particles encapsulated by a phase change polymer. Once the phase change polymer is temporarily melted by transient laser heating, the orientation of the magnetic particles can be re-aligned upon change of a programming magnetic field. By the digital laser writing on selective areas, magnetic anisotropies can be encoded in the composite film and then reprogrammed by repeating the same procedure, thus leading to multimodal 3D shaping under the same actuation magnetic field. Furthermore, we demonstrated their functional applications in assembling multistate 3D structures driven by the magnetic force-induced buckling, fabricating multistate electrical switches for electronics, and constructing reconfigurable magnetic soft robots with locomotion modes of peristalsis, crawling, and rolling.

show abstract

Section: Resultsmentioning

confidence: 71%

Laser reprogramming magnetic anisotropy in soft composites for reconfigurable 3D shaping

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…Electrothermal actuation. Soft electrothermal actuators based on PDMS coated LIG have been reported by Ling et al [104] LIG served as a heater to introduce temperature differences via joule heating. The stress caused by the thermal expansion difference between PI and PDMS could deform 2D structures into 3D architectures via global and local bending.…”

Section: B Thermal Transducersmentioning

confidence: 99%

Physical Sensors Based on Laser-Induced Graphene: A Review

Kaidarova

Kosel

2021

IEEE Sensors J.

View full text Add to dashboard Cite

Physical sensors form the fundamental building blocks of a multitude of advanced applications that detect and monitor the surroundings and communicate the acquired physical data. The everlasting need for more compliant, low-cost, and energy-efficient sensor solutions has led to considerable interest in enhancing their features and operation limits even further. While graphene has emerged as a promising candidate material, due to its outstanding electrical and mechanical properties, it is still not available in large volumes for practical applications. Meanwhile, Laser-Induced Graphene has opened new perspectives for a versatile, durable, printed physical sensing platform capable of detecting various physical parameters across a range of conditions and subjects. In this review, LIG physical sensors were categorized into four broad types based on their transduction mechanism: mechanical, thermal, magnetic, and electromagnetic. We summaries various design strategies established for preparing reliable physical sensors without the involvement of chemical treatments, synthesis, and multi-step fabrication processes. The review considers the effects of laser choice, lasing environment, and parameters on graphene properties. We also discuss a broad spectrum of applications of LIG physical sensors in fields ranging from healthcare, tactile sensing, environmental monitoring, energy harvesting, and soft robotics to desalination and THz modulation.

show abstract

“…Recent studies demonstrate that mechanical metamaterials with optimized microstructure architectures can yield unconventional thermal expansion behaviors, such as near‐zero thermal expansion, [ 1–5 ] negative thermal expansion, [ 6–11 ] and thermally induced shear. [ 12 ] These mechanical metamaterials are of increasing interest, because of their potential for use in applications such as high‐precision space optical systems, [ 13,14 ] adaptive connecting components in satellites, [ 15,16 ] flexible MEMS that require excellent thermal stability, [ 17–24 ] battery electrodes with unique thermal expansion, [ 25–29 ] dental fillings, [ 30 ] thermally controlled shape‐changing structures, [ 12,31–48 ] etc. In response to these opportunities, diverse metamaterial designs have been reported, either for the purpose of maintaining the original shape during temperature changes, or for matching the thermal expansion properties of surrounding/supporting components.…”

Section: Figurementioning

confidence: 99%

Designing Mechanical Metamaterials with Kirigami‐Inspired, Hierarchical Constructions for Giant Positive and Negative Thermal Expansion

Guo

et al. 2020

Advanced Materials

Self Cite

View full text Add to dashboard Cite

Advanced mechanical metamaterials with unusual thermal expansion properties represent an area of growing interest, due to their promising potential for use in a broad range of areas. In spite of previous work on metamaterials with large or ultralow coefficient of thermal expansion (CTE), achieving a broad range of CTE values with access to large thermally induced dimensional changes in structures with high filling ratios remains a key challenge. Here, design concepts and fabrication strategies for a kirigami‐inspired class of 2D hierarchical metamaterials that can effectively convert the thermal mismatch between two closely packed constituent materials into giant levels of biaxial/uniaxial thermal expansion/shrinkage are presented. At large filling ratios (>50%), these systems offer not only unprecedented negative and positive biaxial CTE (i.e., −5950 and 10 710 ppm K−1), but also large biaxial thermal expansion properties (e.g., > 21% for 20 K temperature increase). Theoretical modeling of thermal deformations provides a clear understanding of the microstructure–property relationships and serves as a basis for design choices for desired CTE values. An Ashby plot of the CTE versus density serves as a quantitative comparison of the hierarchical metamaterials presented here to previously reported systems, indicating the capability for substantially enlarging the accessible range of CTE.

show abstract

Laser‐Induced Graphene for Electrothermally Controlled, Mechanically Guided, 3D Assembly and Human–Soft Actuators Interaction

Cited by 137 publications

References 54 publications

Laser reprogramming magnetic anisotropy in soft composites for reconfigurable 3D shaping

Laser reprogramming magnetic anisotropy in soft composites for reconfigurable 3D shaping

Physical Sensors Based on Laser-Induced Graphene: A Review

Designing Mechanical Metamaterials with Kirigami‐Inspired, Hierarchical Constructions for Giant Positive and Negative Thermal Expansion

Contact Info

Product

Resources

About