Physchem

Bio-inspired superhydrophobic coatings have garnered significant attention in recent years due to their potential in creating self-cleaning and anti-icing surfaces. Drawing inspiration from natural systems such as lotus leaves and insect wings, these coatings leverage hierarchical nanostructures to achieve extreme water repellency and low surface adhesion. This review explores recent advances in the design, fabrication, and functional performance of bio-inspired superhydrophobic materials, with a focus on hierarchical micro/nanostructured surfaces. We discuss the underlying mechanisms of wettability, the role of surface chemistry, and the integration of durable nanostructures for enhanced durability. Additionally, the paper discusses the latest progress in scalable manufacturing techniques, environmental adaptability, and multifunctional performance, particularly in self-cleaning and anti-icing applications. Emerging trends, such as stimuli-responsive surfaces and smart coatings, are also examined to provide a comprehensive overview of the field. This review discusses the challenges and future directions for translating laboratory-scale innovations into real-world applications, particularly in aerospace, automotive, energy, and infrastructure sectors.

Quasi-one-dimensional (quasi-1D) topological matter Bi₄X₄ (X = Br, I) possesses versatile topological phases determined by its molar ratio of halide and the stacking mode. Establishing the intrinsic relationship between these topological orders and the quantum transport properties is extremely crucial for both of fundamental research and device applications. Here we review the recent work on the characteristic quantum transport behavior of the Bi₄X₄ system originating from various electronic states, including three-dimensional (3D) bulk states, two-dimensional (2D) surface states, and one-dimensional (1D) topological hinge states. Specifically, variable range hopping effect, Lifshitz transition, metal–insulator transition, and Shubnikov de Haas oscillations are evoked by the gapped bulk states with significant doping carriers. In 2D limits, the (100) surface states exhibit Dirac-type dispersion to produce weak antilocalization, which is a strong 1D nature due to quasi-1D crystal and electronic structure and evidenced by anomalous planar Hall effect. Last but not the least, coherent transport with Aharonov–Bohm oscillations is observed in thin-layer devices, implying the existence of 1D topological hinge states separated by the (100) surface. These unconventional quantum transport features verify the topological nature of Bi₄X₄ in different dimensions, signifying an ideal platform to design and utilize multiple topological orders in this quasi-one-dimensional material system.

One-pot hydrothermal synthesis of boron nitride quantum dots (BNQDs) offers a simple and widely accessible approach to produce nanoparticles with tailored properties for biomedical purposes, including bioimaging and drug delivery. However, growing evidence suggests that most reported BNQD syntheses yield products with insufficient purity and poorly defined structures, limiting their bioapplications where precise composition and controlled synthesis are paramount. In this study, we present a formation mechanism and demonstrate multiple BNQD synthesis pathways that can be precisely controlled by modulating the reaction equilibrium during hydrothermal synthesis under varying experimental conditions. We demonstrate that carbon-related defects shift BNQD photoluminescence (PL) from the UV to the 400–450 nm region, making them suitable for bioimaging, while BO₂⁻ enrichment introduces additional phosphorescence. Furthermore, we show that as-synthesized BNQD suspensions contain significant contamination by non-luminescent ammonium polyborate salts, which is overlooked in prior studies, and disclose the mechanism of their formation as well as effective purification method. Finally, we assess the biocompatibility of purified BNQDs with tuned PL properties and demonstrate their application in bioimaging using Vero cells. The elucidated nanoparticle formation mechanisms, combined with methods for precise control of optical properties, structural defects and sample purity, enable the reproducible production of reliable and effective BNQDs for bioimaging.