Micro/Nanoscale 3D Assembly by Rolling, Folding, Curving, and Buckling Approaches

Xu, Cheng; Zhang, Yihui

doi:10.1002/adma.201901895

Cited by 92 publications

(81 citation statements)

References 217 publications

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“…In addition to the intrinsic strain-induced assembly, the external stress enables the transformation from 2D sheets to 3D mesostructures on the microscopic scale due to the flexibility of materials, similar to origami arts. [65] Attributed to the microscale, capillary forces become considerable compared with bulk forces, resulting in possibilities to tune structures by controlling the surface tension. The interaction between capillary and elastic forces generates the distinguished deflection of planar objects, which drives the folding assembly from submillimeter to micrometers.…”

Section: External Strain Tuning For 3d Mesostructuresmentioning

confidence: 99%

Inorganic Stimuli‐Responsive Nanomembranes for Small‐Scale Actuators and Robots

Tian

Wang

Chen

et al. 2020

Advanced Intelligent Systems

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The term small‐scale robotics describes a wide variety of miniature robotic systems, ranging from millimeter‐sized devices down to autonomous mobile systems with dimensions measured in nanometers. These systems can perform complex tasks that are impossible for humans to accomplish or at scales that humans cannot reach. In recent years, the rapid advancement of small‐scale robotics has benefited from the progress in synthesis and nanotechnology, providing access to nanomembranes with stimuli‐responsive materials, such as phase transition materials, shape memory alloys, and palladium. These materials are 2D sheets with a thickness ranging from 5 to 500 nm, and they have the ability to change their shape reversibly under extremal stimuli. Together with strain engineering for deterministic assembly, various stimuli‐responsive actuators and robots have been fabricated for medicine, manufacturing, and exploration by endowing them with the combined features of a continuously deformable structure, remote operation, and several degrees of freedom. Herein, the recent achievements in small‐scale actuators and robots based on inorganic stimuli‐responsive nanomembranes are reviewed and their advantages and properties highlighted.

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Section: External Strain Tuning For 3d Mesostructuresmentioning

confidence: 99%

Inorganic Stimuli‐Responsive Nanomembranes for Small‐Scale Actuators and Robots

Tian

Wang

Chen

et al. 2020

Advanced Intelligent Systems

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“…Overcoming this limitation potentially could result in significant applications beyond improving the scalability in device integration technologies. [22,[26][27][28][29] Herein, we report a hybrid 3D printing system that combines DLP and electrohydrodynamic jet (e-jet) printing for the production of transparent and freeform 3D optoelectronic devices Direct 3D printing technologies to produce 3D optoelectronic architectures have been explored extensively over the last several years. [5][6][7][8][9] One of the alternative technologies that can overcome the limitations of photolithography is direct 3D printing, which has been explored extensively during the last several years for purely additive operations in which functional inks are deposited only where they are required for the 3D structures.…”

Section: Doi: 101002/advs201901603mentioning

confidence: 99%

High‐Resolution 3D Printing of Freeform, Transparent Displays in Ambient Air

Park

Kim

et al. 2019

Advanced Science

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“…Because of the compatibility with the well-established planar fabrication technologies, this approach can achieve high-speed, parallel assembly of 3D mesostructures with a broad range of thin-film materials and feature sizes, thereby paving the way to the development of novel micro-devices [7,[33][34][35][36]. Recent progress showed that strategic designs of 2D precursor structures [28,29,37] and deformable substrates [38][39][40] as well as the integration schemes [41][42][43][44] can substantially enrich the accessible range of 3D topologies. For example, the structured elastomer substrates with kirigami designs can introduce local rotational motions of the bonding sites to enable the formation of structures with chiral features and morphable shapes [39].…”

Section: Introductionmentioning

confidence: 99%

An Inverse Design Method of Buckling-Guided Assembly for Ribbon-Type 3D Structures

Fan

et al. 2019

Journal of Applied Mechanics

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Mechanically guided three-dimensional (3D) assembly based on the controlled buckling of pre-designed 2D thin-film precursors provides deterministic routes to complex 3D mesostructures in diverse functional materials, with access to a broad range of material types and length scales. Existing mechanics studies on this topic mainly focus on the forward problem that aims at predicting the configurations of assembled 3D structures, especially ribbon-shaped structures, given the configuration of initial 2D precursor and loading magnitude. The inverse design problem that maps the target 3D structure onto an unknown 2D precursor in the context of a prescribed loading method is essential for practical applications, but remains a challenge. This paper proposes a systematic optimization method to solve the inverse design of ribbon-type 3D geometries assembled through the buckling-guided approach. In addition to the torsional angle of the cross section, this method introduces the non-uniform width distribution of the initial ribbon structure and the loading mode as additional design variables, which can significantly enhance the optimization accuracy for reproducing the desired 3D centroid line of the target ribbon. Extension of this method allows the inverse design of entire 3D ribbon configurations with specific geometries, taking into account both the centroid line and the torsion for the cross section. Computational and experimental studies over a variety of elaborate examples, encompassing both the single-ribbon and ribbon-framework structures, demonstrate the effectiveness and applicability of the developed method.

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Micro/Nanoscale 3D Assembly by Rolling, Folding, Curving, and Buckling Approaches

Cited by 92 publications

References 217 publications

Inorganic Stimuli‐Responsive Nanomembranes for Small‐Scale Actuators and Robots

Inorganic Stimuli‐Responsive Nanomembranes for Small‐Scale Actuators and Robots

High‐Resolution 3D Printing of Freeform, Transparent Displays in Ambient Air

An Inverse Design Method of Buckling-Guided Assembly for Ribbon-Type 3D Structures

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