Highly repellent surfaces are constantly being sought in a number of industrial sectors, where accumulation of unwanted material (ice, debris, insects etc...) can cause serious detriment of function. Conventional highly repellent materials do not have the superlative repellence of some of the latest innovations in superhydrophobic/oleophobic coatings, but do have the advantage of durability in many applications. Emerging technologies for nanostructured coatings have significant potential for the development of very high performance surfaces. However, the lack of retention of functional capability is widely recognized as the primary barrier to industrial adoption. The need for a nanostructured hierarchy and low surface energy is widely accepted as providing the underpinning capability for superhydrophobicity/oleophobicity. However, the lack of understanding of the wear mechanism in such coatings and lack of recognized test methodologies enables that comparison of various approaches to achieve repellence hinders effective progress of effective coatings and surface treatments. In the present work, new assessment criteria that allow the performance characteristics of repellent coatings to be compared have been established and implemented. Fundamental to these new criteria is a determination of the repellence, and the retention of the repellence when exposed to mechanical damage. The focus to date has been on abrasive and adhesive wear; nonetheless, versatility of this new classification system allows adapting it for the other forms of coatings damage. Novel approach for evaluation of repellent surfaces gives basics for the development of global figure of merit that helps the progress in development of highly repellent surfaces.

• 出版日期2017-11-15