Your search keyword '"Feng, Yawei"' showing total 2 results

1. Achieving Extreme Pressure Resistance to Liquids on a Super‐Omniphobic Surface with Armored Reentrants.

Author

Sun, Pengcheng, Jin, Yuankai, Yin, Yingying, Wu, Chenyang, Song, Chuanhui, Feng, Yawei, Zhou, Peiyang, Qin, Xuezhi, Niu, Yusheng, Liu, Qiankai, Zhang, Jie, Wang, Zuankai, and Hao, Xiuqing

Subjects

SURFACE tension, STATIC pressure, ACTIVATION energy, LASER machining, SURFACE structure

Abstract

Static repellency and pressure resistance to liquids are essential for high‐performance super‐omniphobic surfaces. However, these two merits appear mutually exclusive in conventional designs because of their conflicting structural demands: Static liquid repellency necessitates minimal solid–liquid contact, which in turn inevitably undercuts the surface's ability to resist liquid invasion exerted by the elevated pressure. Here, inspired by the Springtail, these two merits can be simultaneously realized by structuring surfaces at two size scales, with a micrometric reentrant structure providing static liquid repellency and a nanometric reentrant structure providing pressure resistance, which dexterously avoids the dilemma of their structural conflicts. The nanometric reentrants are densely packed on the micrometric ones, serving as "armor" that prevents liquids invasion by generating multilevel energy barriers, thus naming the surface as the armored reentrants (AR) surface. The AR surface could repel liquids with very low surface tensions, such as silicone oil (21 mN m−1), and simultaneously resist great pressure from the liquids, exemplified by enduring the impact of low‐surface‐tension liquids under a high weber number (>400), the highest‐pressure resistance ever reported. With its scalable fabrication and enhanced performance, our design could extend the application scope of liquid‐repellent surfaces toward ultimate industrial settings. [ABSTRACT FROM AUTHOR]

Published

2024

2. Turbo‐Synergistic Oily Wastewater Remediation in Bio‐Inspired Cone Array Barrel.

Author

Wang, Bing, Luo, Xianfeng, Feng, Yawei, Yang, Linfeng, Zhang, Chunhui, Dong, Zhichao, Jiang, Lei, and Dai, Haoyu

Subjects

CORIOLIS force, SEWAGE, WATER purification, OIL spill cleanup, CONES, CENTRIFUGAL force

Abstract

Oily wastewater discharge causes not only the pollution of environment but also the waste of resources. Existing technologies for wastewater remediation, such as membrane and particle methods, are variable and effective, but are difficult for achieving continuous and rapid oil–water separation. Here, with the synergy of turbo stirring, a strategy for emulsion separation is demonstrated based on the bio‐inspired cone array barrel. Under the centrifugal force, oil droplets in emulsion are thrown onto the cones arrayed on inner wall due to the Coriolis effect, captured by microstructures on cone surface and then penetrate out through the superhydrophobic pores, while only the remediated water remains. The separation technique maintains a high efficiency of above 99.5% for over 30 times of use, as well as for emulsions with variable ingredients. This structure‐dynamics synergistic separation strategy evolves the future technologies on water purification in industrial and daily processes. [ABSTRACT FROM AUTHOR]

Published

2022