Long-distance self-driving method for liquid drop on wetted gradient surfaces

A gradient surface, self-driven technology, applied in the process of producing decorative surface effects, nanotechnology for materials and surface science, decorative arts, etc., can solve unsatisfactory, limit moving distance, reduce droplet driving force and other problems, to achieve the effect of novel design and optimized lag

Inactive Publication Date: 2018-01-30
邱丹丹
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  • Abstract
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  • Claims
  • Application Information

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Problems solved by technology

However, this small wetting gradient range reduces the driving force for liquid droplets to move on the surface of the wetting gradient, limits the moving distance, and cannot meet the higher needs of industry development.

Method used

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  • Long-distance self-driving method for liquid drop on wetted gradient surfaces
  • Long-distance self-driving method for liquid drop on wetted gradient surfaces
  • Long-distance self-driving method for liquid drop on wetted gradient surfaces

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Embodiment Construction

[0026] In order to make the technical means, creative features, goals and effects achieved by the present invention easy to understand, the present invention will be further described below in conjunction with specific illustrations.

[0027] see figure 1 , a long-distance self-driving method for droplets on a wetting gradient surface. The wetting gradient surface is composed of uniform silicon oxide stripes and silicon nanoneedle structures. The top of the wetting gradient solid surface stripes is made of silicon oxide with a static contact angle of 15.5°. The bottom of the wetting gradient solid is a silicon nanoneedle structure that adopts deep reactive ion etching. The static contact angle of the silicon nanoneedle is 166.0°. The alternate phase structure of the hydrophilic and hydrophobic stripes, adjust the area ratio of the hydrophilic and hydrophobic materials, design the surface of different wetted regions with wettability differences, and connect these wetted regions...

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Abstract

The invention discloses a long-distance self-driving method for liquid drop on wetted gradient surfaces. The wetted gradient surfaces comprise uniform silicon oxide stripes and silicon nano-needle structures. Silicon oxide with static contact angles of 15.5 degrees is arranged on hydrophilic regions on the surfaces of wetted gradient solid, the silicon nano-needle structures etched by the aid of deep reactive ions are arranged at the bottoms of the wetted gradient solid, static contact angles of silicon nano-needles are 166.0 degrees, and lag angles of the silicon nano-needles are 3.0 degrees.The long-distance self-driving method has the advantages that the surface wetted gradient ranges of the solid can be greatly expanded and can reach 150 degrees at least, lag phenomena of front and rear contact lines of the liquid drop can be optimized, and the tiny liquid drop with the sizes of 38 mm can be self-driven over long distances; diversified directional self-driving movement paths are designed for the liquid drop, and the long-distance self-driving method is novel in design and is an excellent innovation scheme.

Description

technical field [0001] The invention relates to a microfluidic control system, in particular to a long-distance self-driving method for liquid droplets on a surface with a wetting gradient. Background technique [0002] In microfluidic systems, the directional self-driving of droplets without external force, especially in chemical analysis, biomedicine, etc., has attracted widespread attention at home and abroad. Oriented self-actuation of droplets usually requires external energy (active or passive) to overcome the inherent contact line hysteresis at the solid-liquid interface. The common methods to break the wetting symmetry of solid surface are: chemical gradient, topological gradient, topological gradient, temperature gradient, electromagnetic force, mechanical vibration, pH value induction and the mixture of various methods. Among these methods, wetting gradients on solid surfaces prepared by topology and chemical material inhomogeneity have attracted much attention du...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B81C1/00B82Y30/00
Inventor 邱丹丹
Owner 邱丹丹
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