Vapor-Induced Liquid Collection and Microfluidics on Superlyophilic Substrates

Unravelling the aerodynamic enhancement of water harvesting via dynamic liquid bumps

Harvesting atmospheric water offers a sustainable solution to water scarcity in arid regions. While previous reports that proved the wettability of materials play a crucial role in the fog collection process, the underlying mechanism remains unclear. Despite the focus on convex-backed beetles, hydrophobic smooth-backed beetles like Onymacris unguicularis also efficiently harvest fog. Through comprehensive investigation, the enhancement of fog collection efficiency on hydrophobic surfaces was attributed to the in situ 3D patterning process of microdroplets. Hydrophobic surfaces form dynamic liquid bumps that disturb airflow, improving the capture of tiny fog droplets. With a harp-like collector configuration, the superhydrophobic surface further enhances efficiency by 57% compared to superhydrophilic collectors. COMSOL Multiphysics simulations show that surfaces with stronger hydrophobicity and lower contact angle hysteresis intercept fog droplets more effectively. This work provides insights into the aerodynamic role of wettability in fog harvesting and offers guidelines for developing high-performance, bioinspired fog collectors with optimized material properties.

Dual-solvent-induced persistent nanoscale wet film for controllable two-dimensional molecular crystallization toward polarization-sensitive photodetectors

Two-dimensional organic semiconductor single crystals (2D OSSCs) have great potential for use in high-performance optoelectronic devices. However, challenges associated with controlling complex fluid dynamics and molecular mass transfer during solution-based processes hinder large-scale high-quality production. To address this issue, we developed a nanoconfinement-driven approach for controlling molecular crystallization, improving isotropic molecular mass transfer in fluids, and regulating the morphology of the 2D molecular film. Using a dual-solvent strategy, we created a stable nanoscale extended evaporation meniscus that modulates molecular nucleation and growth dynamics, thereby facilitating the direct shift from one-dimensional to two-dimensional crystals. Dual solvents are essential for generating and maintaining nanoscale wet films during meniscal recession, which is crucial for 2D crystal engineering. Mechanistic studies revealed that adhesion in a dual-solvent system is vital for meniscus formation while disjoining pressure maintains its stability. We also systematically evaluated several [1]benzothieno[3,2-b][1]benzothiophenes (BTBTs) bearing various alkyl chains, which revealed how molecular interactions affect morphology during printing. Organic-field-effect transistors fabricated using 2D OSSCs have significantly higher carrier mobilities than those with striped structures. Moreover, the highly ordered 2D C8-BTBT single-crystal thin film exhibited high sensitivity to polarized ultraviolet light, boasting a dichroic ratio of 2.80 and demonstrating exceptional imaging capabilities for polarized ultraviolet light.

Fluid Control on Bionics-Energized Surfaces

Engineered surfaces play a vital role in various fluid applications, serving specific functions such as self-cleaning, anti-icing, thermal management, and water energy harvesting. In nature, biological surfaces, particularly those displaying physiochemical heterogeneity, showcase remarkable fluid behaviors and functionalities, offering valuable insights for artificial designs. In this Review, we focus on exploring the fascinating fluid phenomena observed on natural biological surfaces and the manipulation of fluids on bioengineered surfaces, with a particular emphasis on droplets, liquid flows, and vapor flows. We delve into the fundamental principles governing symmetric fluid motion on homogeneous surfaces and directed fluid motion on heterogeneous surfaces. We discuss surface design strategies tailored to different fluid scenarios, outlining the strengths and limitations of engineered surfaces for specific applications. Additionally, the challenges faced by engineered surfaces in real-world fluid applications are put forward. By highlighting promising research directions, we hope to stimulate advancements in bioinspired engineering and fluid science, paving the way for future developments.

Designing Versatile Superhydrophilic Structures via an Alginate-Based Hydrophilic Plasticene

The rational design of superhydrophilic materials with a controllable structure is a critical component in various applications, including solar steam generation, liquid spontaneous transport, etc. The arbitrary manipulation of the 2D, 3D, and hierarchical structures of superhydrophilic substrates is highly desirable for smart liquid manipulation in both research and application fields. To design versatile superhydrophilic interfaces with various structures, here we introduce a hydrophilic plasticene that possesses high flexibility, deformability, water absorption, and crosslinking capabilities. Through a pattern-pressing process with a specific template, 2D prior fast spreading of liquids at speeds up to 600 mm/s was achieved on the superhydrophilic surface with designed channels. Additionally, 3D superhydrophilic structures can be facilely designed by combining the hydrophilic plasticene with a 3D-printed template. The assembly of 3D superhydrophilic microstructure arrays were explored, providing a promising route to facilitate the continuous and spontaneous liquid transport. The further modification of superhydrophilic 3D structures with pyrrole can promote the applications of solar steam generation. The optimal evaporation rate of an as-prepared superhydrophilic evaporator reached ~1.60 kg·m^-2·h^-1 with a conversion efficiency of approximately 92.96%. Overall, we envision that the hydrophilic plasticene should satisfy a wide range of requirements for superhydrophilic structures and update our understanding of superhydrophilic materials in both fabrication and application.

Judicious Design and Rapid Manufacturing of a Flexible, Mechanically Resistant Liquid-Like Coating with Strong Bonding and Antifouling Abilities

Fluorine-free liquid-repellent coatings have been highly demanded for a variety of applications. However, rapid formation of coatings possessing outstanding oil repellency and strong bonding ability as well as good mechanical strength (e.g., bendability, impact resistance, and scratch resistance) remains a grand challenge. Herein, a robust strategy to rapidly create fluorine-free oil-repellent coatings in only 30 s via rational design of a semi-interpenetrating polymer network structure is reported. The resulting coating manifests strong bonding capability both in air and underwater. More importantly, it not only provides unprecedented oil repellency, even to high-viscosity crude oil, but also achieves both excellent bendability and hardness. This simple yet effective design strategy opens up a new avenue to manufacture multifunctional materials and devices with desirable features and structural complexities for applications in sustainable antifouling, drag reduction, nondestructive transportation, liquid collection, and biomedicine, among other areas.

Size-Dependent Dried Colloidal Deposit and Particle Sorting via Saturated Alcohol Vapor-Mediated Sessile Droplet Spreading

We experimentally and theoretically investigate a distinct problem of spreading, evaporation, and the associated dried deposits of a colloidal particle-laden aqueous sessile droplet on a surface in a saturated alcohol vapor environment. In particular, the effect of particle size on monodispersed suspensions and efficient self-sorting of bidispersed particles have been investigated. The alcohol vapor diffuses toward the droplet's curved liquid-vapor interface from the far field. The incoming vapor mass flux profile assumes a nonuniform pattern across the interface. The alcohol vapor molecules are adsorbed at the liquid-vapor interface, which eventually leads to absorption into the droplet's liquid phase due to the miscibility. This phenomenon triggers a liquid-vapor interfacial tension gradient and causes a reduction in the global surface tension of the droplet. This results in a solutal Marangoni flow recirculation and spontaneous droplet spreading. The interplay between these phenomena gives rise to a complex internal fluid flow within the droplet, resulting in a significantly modified and strongly particle-size-dependent dried colloidal deposit. While the smaller particles form a multiple ring pattern, larger particles form a single ring, and additional "patchwise" deposits emerge. High-speed visualization of the internal liquid-flow revealed that initially, a ring forms at the first location of the contact line. Concurrently, the Marangoni flow recirculation drives a collection of particles at the liquid-vapor interface to form clusters. Thereafter, as the droplet spreads, the smaller particles in the cluster exhibit a "jetlike" outward flow, forming multiple ring patterns. In contrast, the larger particles tend to coalesce together in the cluster, forming the "patchwise" deposits. The widely different response of the different-sized particles to the internal fluid flow enables an efficient sorting of the smaller particles at the contact line from bidispersed suspensions. We corroborate the measurements with theoretical and numerical models wherever possible.

Extremely Uniform Graphene Oxide Thin Film as a Universal Platform for One-Step Biomaterial Patterning

Graphene oxide (GO) has proven to be a highly promising material across various biomedical research avenues, including cancer therapy and stem cell-based regenerative medicine. However, creating a uniform GO coating as a thin layer on desired substrates has been considered challenging owing to the intrinsic variability of the size and shape of GO. Herein, a new method is introduced that enables highly uniform GO thin film (UGTF) fabrication on various biocompatible substrates. By optimizing the composition of the GO suspension and preheating process to the substrates, the "coffee-ring effect" is significantly suppressed. After applying a special postsmoothing process referred to as the low-oxygen concentration and low electrical energy plasma (LOLP) treatment, GO is converted to small fragments with a film thickness of up to several nanometers (≈5.1 nm) and a height variation of only 0.6 nm, based on atomic force microscopy images. The uniform GO thin film can also be generated as periodic micropatterns on glass and polymer substrates, which are effective in one-step micropatterning of both antibodies and mouse melanoma cells (B16-F10). Therefore, it can be concluded that the developed UGTF is useful for various graphene-based biological applications.