Micro-/Nanohierarchical Structures Physically Engineered on Surfaces: Analysis and Perspective

Abstract

The high demand for micro-/nanohierarchical structures as components of functional substrates, bioinspired devices, energy-related electronics, and chemical/physical transducers has inspired their in-depth studies and active development of the related fabrication techniques. In particular, significant progress has been achieved in hierarchical structures physically engineered on surfaces, which offer the advantages of wide-range material compatibility, design diversity, and mechanical stability, and numerous unique structures with important niche applications have been developed. This review categorizes the basic components of hierarchical structures physically engineered on surfaces according to function/shape and comprehensively summarizes the related advances, focusing on the fabrication strategies, ways of combining basic components, potential applications, and future research directions. Moreover, the physicochemical properties of hierarchical structures physically engineered on surfaces are compared based on the function of their basic components, which may help to avoid the bottlenecks of conventional single-scale functional substrates. Thus, the present work is expected to provide a useful reference for scientists working on multicomponent functional substrates and inspire further research in this field. In recent decades, significant progress has been achieved in micro-/nanohierarchical structures physically engineered on surfaces. This review summarizes the recent advances in the development of such structures, provides a classification of their basic constituents according to function and shape, and discusses the related fabrication strategies, ways of combining basic components, potential applications, and future research directions.image