A Lotus‐Leaf‐like Superhydrophobic Surface: A Porous Microsphere/Nanofiber Composite Film Prepared by Electrohydrodynamics

Jiang, Lei; Zhao, Yong; Zhai, Jin

doi:10.1002/anie.200460333

Cited by 936 publications

(628 citation statements)

References 48 publications

(25 reference statements)

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“…Via this simple method a cheap industrial polymer affords superhydrophobicity without any further modification. [82] porous microspheres (Fig. 8) contribute to the superhydrophobicity by increasing the surface roughness, while nanofibers interweave to form a 3D network and reinforce the composite film that is surprisingly similar to a lotus leaf.…”

Section: Superhydrophobic Surfacesmentioning

confidence: 99%

“…Different chemical and physical methods for the fabrication of rough surfaces and subsequent application of low-surface-energy coatings on these rough surfaces have been explored, e.g., lithography, [77] sublimation, [78] plasma techniques, [79] self-assembled monolayers, [80] electrochemical methods, [81] electrohydrodynamic/electrospinning techniques, [82] and many more. Electrohydrodynamic techniques proved to be effective methods for the preparation of lotus-leaf-like porous microsphere/nanofiber composite films.…”

Section: Superhydrophobic Surfacesmentioning

confidence: 99%

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Bio‐Inspired, Smart, Multiscale Interfacial Materials

2008

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In this review a strategy for the design of bioinspired, smart, multiscale interfacial (BSMI) materials is presented and put into context with recent progress in the field of BSMI materials spanning natural to artificial to reversibly stimuli‐sensitive interfaces. BSMI materials that respond to single/dual/multiple external stimuli, e.g., light, pH, electrical fields, and so on, can switch reversibly between two entirely opposite properties. This article utilizes hydrophobicity and hydrophilicity as an example to demonstrate the feasibility of the design strategy, which may also be extended to other properties, for example, conductor/insulator, p‐type/n‐type semiconductor, or ferromagnetism/anti‐ferromagnetism, for the design of other BSMI materials in the future.

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Section: Superhydrophobic Surfacesmentioning

confidence: 99%

Section: Superhydrophobic Surfacesmentioning

confidence: 99%

Bio‐Inspired, Smart, Multiscale Interfacial Materials

2008

Self Cite

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“…27 Bottomup approaches involve mostly self-assembly and self-organization 28 as for instance chemical deposition, 29 layer-by-layer (LBL) deposition, 30 hydrogen bonding, 31 and colloidal assemblies. 32 There are also methods based on the combination of both bottom-up and top-down approaches, for example, casting of polymer solution and phase separation, 33 and electrospinning. 34 Among these methods, the application using two-dimensional (2D) colloidal crystals, "natural lithography", which has been suggested by Deckman and Dunsmuir, 35 has attracted attention due to it being a relatively easy process in comparison with conventional lithography.…”

mentioning

confidence: 99%

Reducing the Adhesion between Surfaces Using Surface Structuring with PS Latex Particle

Dejeu

Bechelany

Philippe

et al. 2010

ACS Appl. Mater. Interfaces

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The adhesion between a micro-object and a microgripper end-effector is an important problem in micromanipulation. Canceling or reducing this force is a great challenge. This force is directly linked to the surface chemical structure of the object and the gripper. We propose to reduce the adhesion force by using a self-assembled monolayer structuring on one surface. The surface was structured by polystyrene latex particles (PS particles) with radii from 100 to 1500 nm. The adhesion force measurements obtained by AFM were compared to a multisphere van der Waals force model. The model suggests the existence of an optimal value of the sphere radius which minimizes the adhesion. In that case, the pull-off force is reduced to 20 nN by the PS particles layer with a radius of 45 nm. A wide range of applications in the field of telecommunications, bioengineering, and more generally speaking, MEMS can be envisaged for these substrates.

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“…36 Bottom-up approaches involve mostly self-assembly and self-organization 37 as for instance chemical deposition, 38 layer-by-layer (LBL) deposition, 39 and colloidal assemblies. 40 There are also methods based on the combination of both bottom-up and top-down approaches, for example, casting of polymer solution and phase separation, 41 and electrospinning. 42 Among these methods, the application using two-dimensional (2D) colloidal crystals, called "natural lithography", which has been suggested by Deckman and Dunsmuir, 43 has attracted attention due to it being a relatively easy process in comparison with conventional lithography technique.…”

mentioning

confidence: 99%

Adhesion Control for Micro- and Nanomanipulation

et al. 2011

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The adhesion between a micro/nano-object and a micro-gripper end-effector is an important problem in micromanipulation. Cancelling or reduction this force is a great challenge.This force is directly linked to the surface chemical structure of the object and the gripper. We propose to predict this force between a structuring surface and a micro-object with a multisphere van der Waals force model. The surface was structured by polystyrene latex particles (PS particles) with radii from 35 to 2000 nm. The model was compared with experimental pulloff force measurement performed by AFM with different natures of spheres materials glued on the tipless. A wide range of applications, in the field of telecommunications, bioengineering, and more generaly speaking MEMS can be envisaged for these substrates. † FEMTO-ST Institute ‡ IEMM ¶ EMPA

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A Lotus‐Leaf‐like Superhydrophobic Surface: A Porous Microsphere/Nanofiber Composite Film Prepared by Electrohydrodynamics

Cited by 936 publications

References 48 publications

Bio‐Inspired, Smart, Multiscale Interfacial Materials

Bio‐Inspired, Smart, Multiscale Interfacial Materials

Reducing the Adhesion between Surfaces Using Surface Structuring with PS Latex Particle

Adhesion Control for Micro- and Nanomanipulation

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