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Solar-driven water evaporation represents an environmentally benign method of water purification/desalination. However, the efficiency is limited by increased salt concentration and accumulation. Here, we propose an energy reutilizing strategy based on a bio-mimetic 3D structure. The spontaneously formed water film, with thickness inhomogeneity and temperature gradient, fully utilizes the input energy through Marangoni effect and results in localized salt crystallization. Solar-driven water evaporation rate of 2.63 kg m −2  h −1 , with energy efficiency of >96% under one sun illumination and under high salinity (25 wt% NaCl), and water collecting rate of 1.72 kg m −2  h −1 are achieved in purifying natural seawater in a closed system. The crystalized salt freely stands on the 3D evaporator and can be easily removed. Additionally, energy efficiency and water evaporation are not influenced by salt accumulation thanks to an expanded water film inside the salt, indicating the potential for sustainable and practical applications. Solar-driven water evaporation technology still faces main challenges of limited efficiency and salt fouling. Here the authors achieve high energy efficiency and evaporation rate under high salinity through an energy reutilizing strategy based on interfacial water film inhomogeneity on a biomimetic structure.

Developing an effective and sustainable method for separating and purifying oily wastewater is a significant challenge. Conventional separation membrane and sponge systems are limited in their long-term usage due to weak antifouling abilities and poor processing capacity for systems with multiple oils. In this study, we present a dual-bionic superwetting gears overflow system with liquid steering abilities, which enables the separation of oil-in-water emulsions into pure phases. This is achieved through the synergistic effect of surface superwettability and complementary topological structures. By applying the surface energy matching principle, water and oil in the mixture rapidly and continuously spread on preferential gear surfaces, forming distinct liquid films that repel each other. The topological structures of the gears facilitate the overflow and rapid transfer of the liquid films, resulting in a high separation flux with the assistance of rotational motion. Importantly, this separation model mitigates the decrease in separation flux caused by fouling and maintains a consistently high separation efficiency for multiple oils with varying densities and surface tensions. Developing efficient separation methods for oily wastewater holds significant global importance. In this study, the authors combine supewettability and bio-inspired topological structures to demonstrate a dual-bionic superwetting gear system with liquid directional steering to achieve oil-water separation.

Irrigation is limited by water scarcity. Here, we show how a drip irrigation system inspired by the leaf of the fig tree Ficus religiosa (also known as the bodhi tree) can improve irrigation efficiency. The reverse curvature of the leaf regulates the convergence process of multiple water streams, while its long-tail apex allows for fast water drainage with the droplet separation centroid beyond the leaf apex. We explain why drip frequency increases after the break-up of contact line pinning at the apex tip by using scaling laws for drip volume and analyzing drainage dynamics. We build a drip irrigation emitter inspired by the bodhi leaf apex and compare the germination efficiency of wheat, cotton, and maize under different irrigation modes. These results show that the proposed bodhi-leaf-apex-mimetic (BLAM) drip irrigation can improve water saving while ensuring germination and seedling growth. Drip irrigation mitigates water shortage yet suffers high flow resistance and blockage. Here, the authors design a drip irrigation mechanism inspired by bodhi leaf morphology which can enhance water saving and seedling growth.

Crop production and quality safety system have the potential to nurture human health and improve environmental sustainability. Providing a growing global population with sufficient and healthy food is an immediate challenge. However, this system largely depends on the spraying of agrochemicals. Crop leaves are covered with different microstructures, exhibiting distinct hydrophilic, hydrophobic, or even superhydrophobic wetting characteristics, thus leading to various deposition difficulties of sprayed droplets. Here, the relationship between wettability and surface microstructure in different crop leaves from biological and interfacial structural perspectives is systematically demonstrated. A relational model is proposed in which complex microstructures lead to stronger leaf hydrophobicity. And adding surfactant with a faster dynamically migrating velocity and reducing droplet size can improve agrochemical precise deposition. These contribute toward highly accurate and efficient targeted applications with fewer agrochemicals use and promote sustainable models of eco‐friendly agriculture systems.

Various creatures, such as spider silk and cacti, have harnessed their surface structures to collect fog for survival. These surfaces typically stay dry and have a large contact hysteresis enabling them to move a condensed water droplet, resulting in an intermittent transport state and a relatively reduced speed. In contrast to these creatures, here we demonstrate that Nepenthes alata offers a remarkably integrated system on its peristome surface to harvest water continuously in a humid environment. Multicurvature structures are equipped on the peristome to collect and transport water continuously in three steps: nucleation of droplets on the ratchet teeth, self-pumping of water collection that steadily increases by the concavity, and transport of the acquired water to overflow the whole arch channel of the peristome. The water-wetted peristome surface can further enhance the water transport speed by ∼300 times. The biomimetic design expands the application fields in water and organic fogs gathering to the evaporation tower, laboratory, kitchen, and chemical industry.

Biomimetic materials that use natural wisdom to solve practical problems are developing rapidly. The trend for systematic biomimicry is towards in-situ characterization of natural creatures with high spatial resolutions. Furthermore, rapid reconstruction of digital twin models with the same complex features as the prototype is indispensable. However, it faces bottlenecks and limits in fast characterization and fabrication, precise parameter optimization, geometric deviations control, and quality prediction. To solve these challenges, here, we demonstrate a state-of-the-art method taking advantage of micro-computed tomography and three-dimensional printing for the fast characterization of the pitcher plant Nepenthes x ventrata and fabrication of its biomimetic model to obtain a superior drainage controller with multiscale structures with precise surface morphology optimization and geometric deviation control. The film-rupture-based drainage dynamic and mechanisms are characterized by x-ray and high-speed videography, which determines the crucial structures for unique directional drainage. Then the optimized artificial pitchers are further developed into sustained drainage devices with novel applications, such as detection, reaction, and smoke control. Fast prototype and rapid construction of sustained biomimetic drainage device. Integrated systematic biomimicry manufacturing of digital twin and 3D printing. A superior directional drainage strategy inspired by Nepenthes x ventrata .

Developing robust water-repellent textiles is critical for outdoor, protective, and industrial applications. However, achieving long-lasting water repellency under mechanical stress remains a significant challenge. Conventional approaches typically rely on nanoparticle assemblies or PFAS-based finishes, which often detach or degrade when subjected to abrasion or harsh conditions. Here, we demonstrate a molecularly assembled robust superhydrophobic shell (MARS) technique that directly constructs an ordered, covalently bonded, fluorine-free silica shell on individual yarn fibers via a one-step process. MARS eliminates the need for discrete nanoparticles or fluorinated chemistries and is compatible with a wide range of natural and synthetic fibers. This fiber-level treatment maintains superhydrophobicity even after the fibers are woven or knitted into finished textiles, while preserving breathability and mechanical resilience. MARS combines biomimetic inspiration with practical, scalable fabrication to meet urgent performance needs. Unlike conventional coatings that progressively degrade, the permanently bonded MARS coating endures intensive abrasion, high-velocity water impacts, steam exposure, and extreme temperature cycles. By addressing key challenges such as PFAS restrictions and the fragility of traditional coatings, the MARS method paves the way for next-generation water-repellent fabrics that balance sustainability and high performance across outdoor, protective, medical, and industrial applications.

Diabetes mellitus poses a global health challenge, necessitating natural adjuvants with minimal side effects. The aims of this study were to optimize the concentrations of chromium (Cr), zinc (Zn), and germanium (Ge) in the liquid fermentation media of Pleurotus citrinopileatus and Hericium erinaceus and to evaluate the hypoglycemic efficacy of buccal tablets in diabetic mice. The results showed that the optimal ion concentrations in the liquid fermentation medium were Cr 200 mg/L, Zn 200 mg/L, and Ge 50 mg/L for P. citrinopileatus, and Cr 200 mg/L, Zn 100 mg/L, and Ge 100 mg/L for H. erinaceus. After 3 weeks of administration of high-dose (6 g/kg) P. citrinopileatus and H. erinaceus buccal tablets, a 29.1% reduction in the blood glucose levels of diabetic mice was observed compared with pre-administration. High-dose tablets decreased the levels of total cholesterol, triglyceride, and low-density lipoprotein cholesterol while increasing high-density lipoprotein cholesterol. Compared with negative control, high-dose tablets increased catalase and superoxide dismutase activities by 31.2% and 34.1%, respectively. Moreover, the buccal tablets modulated the diversity and structure of the gut microbiota in mice. Relative abundance of beneficial genera (Lactobacillus, Akkermansia, Bifidobacterium, and Ruminococcus) in the high-dose group were increased, while diabetogenic taxa (Prevotella, Desulfovibrio, and Enterococcus) were inhibited. It is concluded that buccal tablets combining P. citrinopileatus and H. erinaceus treated with Cr, Zn, and Ge significantly ameliorated hyperglycemia, dyslipidemia, and oxidative stress, and reshaped the gut microbiota in diabetic mice, demonstrating the potential of edible mushrooms and trace elements as a natural antidiabetic therapy.

BackgroundThe objective of this study was to observe alterations of serum uric acid (SUA) level and gut microbiota after Roux-en-Y gastric bypass (RYGB) and sleeve gastrectomy (SG) surgery in a hyperuricemic rat model.MethodWe performed Roux-en-Y gastric bypass (RYGB) and sleeve gastrectomy (SG) surgery in a hyperuricemic rat model. Serum uric acid (UA), xanthine oxidase (XO) activity, IL-6, TNF-α and lipopolysaccharide (LPS) level changes, and 16S rDNA of gut microbiota were analyzed.ResultsAfter the surgery, the RYGB and SG procedures significantly reduced body weight, serum UA, IL-6, TNF-α and LPS levels, and XO activity. In addition, the RYGB and SG procedures altered the diversity and taxonomic composition of the gut microbiota. Compared with Sham group, RYGB and SG procedures were enriched in the abundance of phylum Verrucomicrobia and species Akkermansia muciniphila, while the species Escherichia coli was reduced.DiscussionWe here concluded that bariatric surgery-induced weight loss and resolution of inflammatory remarkers as well as changes of gut microbiota may be responsible for the reduced XO activity and SUA level. To have a better understanding of the underlying mechanism of UA metabolism following bariatric surgery, further research is needed.

The melting of Arctic ice has facilitated the successful navigation of merchant ships through the Arctic route, often requiring icebreakers for assistance. To reduce the risk of accidents between merchant vessels and icebreakers stemming from human errors during operations, this paper introduces an enhanced human reliability assessment approach. This method utilizes the Dynamic Bayesian Network (DBN) model, integrated with the information, decision, and action in crew context (IDAC) framework. First, a qualitative analysis of crew maneuvering behavior in scenarios involving a collision with the preceding vessel during icebreaker assistance is conducted using the IDAC model. Second, the D–S evidence theory and cloud models are integrated to process multi-source subjective data. Finally, the human error probability of crew members is quantified using the DBN. The research results indicate that during convoy operations, the maximum probability that the officer on watch (OOW) chooses an incorrect deceleration strategy is 8.259×10−2 and the collision probability is 4.129×10−3. Furthermore, this study also found that the factors of Team Effectiveness and Knowledge/Abilities during convoy operations have the greatest impact on collision occurrence. This research provides important guidance and recommendations for the safe navigation of merchant ships in the Arctic waters. By reducing human errors and adopting appropriate preventive measures, the risk of collisions between merchant ships and icebreakers can be significantly decreased.