Progress in Bioinspired Dry and Wet Gradient Materials from Design Principles to Engineering Applications

Dong, Xiaoxiao; Hong, Zhonghua; Li, Jiapeng; Tian, Yu; Zeng, Hongbo; Ramos, Melvin A.; Hu, Travis Shihao; Xu, Quan

doi:10.1016/j.isci.2020.101749

Cited by 23 publications

(8 citation statements)

References 305 publications

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“…To maximize the survival in the complex, dynamic natural environments, functional gradient structures have been developed in many creatures [ 1 , 2 , 3 , 4 , 5 , 6 , 7 ]. For instance, the microscale setae of the ladybird beetle Coccinella septempunctata have a gradient modulus from 7.2 GPa at the root to 1.2 MPa at the tip, endowing a high flexibility at the seta tip to enhance contact formation and a stiff stalk to maintain mechanical stability [ 6 ].…”

Section: Introductionmentioning

confidence: 99%

Gradient Micropillar Array Inspired by Tree Frog for Robust Adhesion on Dry and Wet Surfaces

et al. 2022

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The strong adhesion on dry and wet surfaces and the durability of bioinspired hierarchical fibrillar adhesives are critical for their applications. However, the critical design for the strong adhesion normally depends on fine sub-micron structures which could be damaged during repeat usage. Here, we develop a tree frog-inspired gradient composite micropillars array (GP), which not only realizes a 2.3-times dry adhesion and a 5.6-times wet adhesion as compared to the pure polydimethylsiloxane (PDMS) micropillars array (PP), but also shows excellent durability over 200 repeating cycles of attachment/detachment and self-cleaning ability. A GP consists of stiffer tips and softer roots by incorporating gradient dispersed CaCO3 nanoparticles in PDMS micropillar stalks. The modulus gradient along the micropillar height facilitates the contact formation and enhances the maximum stress during the detaching. The study here provides a new design strategy for robust adhesives for practical applications in the fields of robotics, electronics, medical engineering, etc.

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Section: Introductionmentioning

confidence: 99%

Gradient Micropillar Array Inspired by Tree Frog for Robust Adhesion on Dry and Wet Surfaces

et al. 2022

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“…In fact, creatures in nature have evolved over tens of thousands of years and gradually developed unique structural and mechanical properties. ese properties allow them to function beyond the man-made systems through using their complex multiscale and multiphase structures [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Lattice Modeling Method with Gradient Functions

Cheng

Dai

et al. 2022

Mobile Information Systems

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Lattice structure materials have great application potential in biomedical, aerospace, and other fields. In fact, designing multilevel structure parametrically to achieve excellent mechanical performance is a challenging task. In this paper, a hierarchical lattice modeling method with gradient functions is proposed on the basis of the multilevel structural characteristics of organisms to solve the problem of the coexistence of high hardness, high strength, and high toughness. The multilevel body space is filled with matching lattices in accordance with the given dynamic parameters, and the design is optimized in accordance with the simulation results. Thus, the desired composite functional structure is generated. In fact, the proposed method is divided into two stages, that is, preprocessing and design. In the former stage, the interpolation method is used to establish a lattice unit model family retrieved by parameters, such as elastic modulus and impact toughness. In the latter stage, the multilevel 3D reconstruction model is initially filled with the gradient multilevel lattices through the global optimization technique with an isosurface modeling algorithm. The porosity, rod diameter, and other parameters of the lattice structure are regulated in accordance with the results of finite element analysis through image mapping, meeting the requirements of biomechanical characteristics. Our empirical evaluation and experimental results demonstrate that the proposed method can control the relationship between porous structure porosity, elastic modulus, and impact toughness and design bionic multispace microstructures close to biodental displacement and deformation.

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“…The transportation of liquid is ubiquitous in nature, [1,2] such as the concave-convex hydrophilic and hydrophobic structure on the desert beetle, [3] the opening of Nepenthes, [4] and the cactus needle structure [5,6] for the collection and directional transportation of water as well as vascular plants for anti-gravity water transpiration. [7,8] The unique multiscale structure gives them excellent liquid transport effects, making them better adapt to the natural environment.…”

Section: Introductionmentioning

confidence: 99%

A Bioinspired Fibrous Helix with Periodic Gradient for Directional Fluidic Gates

Gao

Guo

et al. 2022

Adv Eng Mater

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Liquid transport is of great significance to industry and life, such as microfluidic chip, liquid separation, fluidic gates, and tissue fluid discharge. However, there are still some challenges to achieve well‐controlled directional transports, and the delamination often occurs for the now existing Janus membranes. Herein, fibrous assembly with hierarchically fibrous helix architecture bioinspired by tendrils through electrospinning combined with mechanical twisting technology is engineered and demonstrated. The liquid transport behavior using as fluidic gates by connecting light‐emitting diode (LED) and the resulting liquid separation mechanism were characterized and investigated, respectively. Different from previous materials, due to the existence of distinct periodic alternate gradient interface topology, the hierarchically fibrous helix exhibits a long‐range order and directional liquid transport trajectory as well as improved water management property. This strategy is cost‐effective and can be extended to other fields. The resultant materials are highly promising for applications in actuators, microfluidic chips, and fluidic gates.

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Progress in Bioinspired Dry and Wet Gradient Materials from Design Principles to Engineering Applications

Cited by 23 publications

References 305 publications

Gradient Micropillar Array Inspired by Tree Frog for Robust Adhesion on Dry and Wet Surfaces

Gradient Micropillar Array Inspired by Tree Frog for Robust Adhesion on Dry and Wet Surfaces

Hierarchical Lattice Modeling Method with Gradient Functions

A Bioinspired Fibrous Helix with Periodic Gradient for Directional Fluidic Gates

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