We are excited to announce that our review, titled “Strategies for Achieving Real-World Robustness in Topologically Engineered Surfaces with Special Wettability,” has been accepted by Droplet. Superwetting surfaces with engineered topologies are gaining attention for their ability to customize wetting behaviors and integrate various functionalities, which are crucial for applications in droplet manipulation, microfluidic systems, and energy harvesting. However, existing strategies for randomly structured surfaces often fall short for these specifically engineered surfaces, highlighting the need for a comprehensive review focusing on their durability and robustness.
Our review exclusively addresses the unique challenges faced by engineered topological superwetting surfaces and the development of tailored robustness strategies. We begin by outlining advances in structural design principles essential for achieving customized wettability. The review delves into issues related to robustness and durability, examining the mechanical and chemical principles that contribute to these challenges, including thermal shock, aging, and corrosion.
Past reviews have explored robust design strategies, but real-world applications often face multiple challenges simultaneously. Our review addresses these by presenting case studies from outdoor, underwater, and specialized settings, demonstrating effective solutions. By focusing on structural design and optimizing material selection, we provide practical guidance for enhancing superwetting technologies. This review will offer valuable insights and inspire further research in the field.
我们的綜述文章题为<<Strategies for Achieving Real-World Robustness in Topologically Engineered Surfaces with Special Wettability>>已被 Droplet 接受。具有工程拓扑结构的超润湿表面因其定制润湿行为和集成各种功能的能力而受到关注,这对于液滴作、微流体系统和能量收集中的应用至关重要。然而,现有的随机结构表面策略往往无法满足这些专门设计的表面的需求,这凸显了对其耐用性和坚固性进行全面审查的必要性。
我们的综述专门解决了工程拓扑超润湿表面面临的独特挑战以及定制鲁棒性策略的开发。我们概述了实现定制润湿性所必需的结构设计原则的进步。该评论深入探讨了与坚固性和耐用性相关的问题,研究了导致这些挑战的机械和化学原理,包括热冲击、老化和腐蚀。
过去的评论探讨了稳健的设计策略,但实际应用往往同时面临多种挑战。我们的评论通过介绍户外、水下和专业环境的案例研究来解决这些问题,并展示有效的解决方案。通过注重结构设计和优化材料选择,我们为增强超润湿技术提供了实用指导。 这篇综述 将提供宝贵的见解并激发该领域的进一步研究。