Biologically inspired crack trapping for enhanced adhesion

Glassmaker, Nicholas; Jagota, Anand; Hui, Chung‐Yuen; Noderer, William L.; Chaudhury, Manoj K.

doi:10.1073/pnas.0703762104

Cited by 244 publications

(286 citation statements)

References 39 publications

(59 reference statements)

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“…It is important to note that the last two boundary conditions are satisfied only for fibrils that are well adhered to the indenter. Most investigators use fibrils that have structures at their tips to improve contact and adhesion; for example, Varenberg & Gorb (2007) and Kim & Sitti (2006) used terminal contact plates, whereas Glassmaker et al (2007) and Yao et al (2007) used a terminal continuous thin film. For these fibrils, it is expected that the aforementioned boundary conditions would be satisfied.…”

Section: Dynamic Rod Modelmentioning

confidence: 99%

Buckling of sheared and compressed microfibrils

Nadermann

Kumar

Goyal

et al. 2010

J. R. Soc. Interface.

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In this paper, we study the stability of an initially straight elastic fibril clamped at one end, while the other end is subjected to a constant normal compressive force and a prescribed shear displacement. We found the buckling load of a sheared fibril to be always less than the Euler buckling load. Furthermore, if the end of the fibril loses adhesion, then the buckling load can be considerably less. Our result suggests that the static friction of microfibre arrays can decrease with increasing normal compressive load and, in some cases, friction force can actually become negative.

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Section: Dynamic Rod Modelmentioning

confidence: 99%

Buckling of sheared and compressed microfibrils

Nadermann

Kumar

Goyal

et al. 2010

J. R. Soc. Interface.

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“…Recent interest in bio-inspired adhesives has motivated many researchers to fabricate microfibril arrays (Liu & Bhushan 2003;Peressadko & Gorb 2004;Chung & Chaudhury 2005;Crosby et al 2005;Glassmaker et al 2005Glassmaker et al , 2007Huber et al 2005;Northen & Turner 2005;Yurdumakan et al 2005;Kim & Sitti 2006;Majidi et al 2006;Aksak et al 2007;Gorb et al 2007;Greiner et al 2007; and to study their contact mechanics and adhesion (Jagota & Bennison 2002;Gao et al 2003Gao et al , 2005Persson & Gorb 2003;Hui et al 2004;Persson et al 2005;Spolenak et al 2005a,b;Tang et al 2005;Bhushan et al 2006;Tian et al 2006;Yao & Gao 2006;Chen & Gao 2007). Most of these studies focus on how the interface between the microfibrils and a smooth, hard substrate separates under a normal load.…”

Section: Introductionmentioning

confidence: 99%

Compliance of a microfibril subjected to shear and normal loads

Liu

Hui

Shen

et al. 2008

J. R. Soc. Interface.

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Many synthetic bio-inspired adhesives consist of an array of microfibrils attached to an elastic backing layer, resulting in a tough and compliant structure. The surface region is usually subjected to large and nonlinear deformations during contact with an indenter, leading to a strongly nonlinear response. In order to understand the compliance of the fibrillar regions, we examine the nonlinear deformation of a single fibril subjected to a combination of shear and normal loads. An exact closed-form solution is obtained using elliptic functions. The prediction of our model compares well with the results of an indentation experiment.

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“…For example, many insects perform sliding movements while their feet are in contact with a surface in order to induce shear stresses that not only increase viscous adhesive forces, but help to dislodge contaminants. [63,64] Secreted adhesive fluid also plays a key role in self-cleaning by making it possible to deposit contaminating particles with each step, essentially washing the epidermal layer. [26] The ability of certain insects to strongly fasten themselves to a variety of surfaces is also remarkable.…”

Section: Chemical Adhesives For Stasis and Locomotionmentioning

confidence: 99%

It's Not a Bug, It's a Feature: Functional Materials in Insects

2018

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Over the course of their wildly successful proliferation across the earth, the insects as a taxon have evolved enviable adaptations to their diverse habitats, which include adhesives, locomotor systems, hydrophobic surfaces, and sensors and actuators that transduce mechanical, acoustic, optical, thermal, and chemical signals. Insect‐inspired designs currently appear in a range of contexts, including antireflective coatings, optical displays, and computing algorithms. However, as over one million distinct and highly specialized species of insects have colonized nearly all habitable regions on the planet, they still provide a largely untapped pool of unique problem‐solving strategies. With the intent of providing materials scientists and engineers with a muse for the next generation of bioinspired materials, here, a selection of some of the most spectacular adaptations that insects have evolved is assembled and organized by function. The insects presented display dazzling optical properties as a result of natural photonic crystals, precise hierarchical patterns that span length scales from nanometers to millimeters, and formidable defense mechanisms that deploy an arsenal of chemical weaponry. Successful mimicry of these adaptations may facilitate technological solutions to as wide a range of problems as they solve in the insects that originated them.

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Biologically inspired crack trapping for enhanced adhesion

Cited by 244 publications

References 39 publications

Buckling of sheared and compressed microfibrils

Buckling of sheared and compressed microfibrils

Compliance of a microfibril subjected to shear and normal loads

It's Not a Bug, It's a Feature: Functional Materials in Insects

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