Research Impact



 February 2026 Research Publications




 Interfacial Engineering and Hydrophilic/Hydrophobic  Coatings   Engineering Interfacial Thermal Energy Management via
 in Solar Evaporators: Strategies for Balancing Evaporation and   Grooved B4C-Polyurethane Architectures for High-Efficiency

 Condensation - A Comprehensive Review  Solar-Thermal Desalination





 Author(s):                                            Author(s):


 Irshad, M. S. (Hubei University), Maqsood, G. (Hubei University),  Arshad, N. (Shenzhen University), Shakoor, B.   Fan, X. (Xinjiang Institute of Engineering), Shi, R. (Xinjiang Institute of Engineering), Ahmed, I. (Abu Dhabi University),
 (University of Wah), Ahmed, I. (Abu Dhabi University), Ali, M. A. (Hubei University), Asghar, M. S. (Hubei University),   Howells, C. T. (Abu Dhabi University), Al Huwayz, M. (Princess Nourah bint Abdulrahman University), Alomar, M. (Princess
 Li, W. (Hubei University), Li, W. (Hubei University), Mushtaq, N. (Hubei University), Ghazanfar, U. (University of Wah),   Nourah bint Abdulrahman University), Shakoor, B. (University of Wah), Shah, M. (University of Wah), Arshad, N. (Hubei
 Rehman, S. U. (Euromed University of Fes),  Sabir, M. (Wuhan University of Technology), Saqib, M. (University of   University), Ha, V. T. H. (PHENIKAA University), Lien, D. T. (PHENIKAA University), Dao, V.-D. (PHENIKAA University),
 Bologna), Mei, T. (Hubei University), Tianxiang, Z. (Hubei University), Shamim, T. (Northern Illinois University), Zhang, J.   Sultan Irshad, M. (Hubei University)
 (Suzhou University of Science and Technology), Wang, H. (Shenzhen University), Dao, V.-D. (PHENIKAA University), Ho,
 N. X. (PHENIKAA University), Wang, X. (Hubei University)  Index Terms:


 Index Terms:   Cost effectiveness; Effluents; Engineering research; Evaporators; Hydrophilicity; Metal ions; Salt removal; Thermal
        Engineering; Wastewater treatment; Fresh Water; Groove-engineered; Grooved structures; Higher efficiency;
 Coatings; Condensers (liquefiers); Conversion efficiency; Evaporation; Evaporators; Hydrophilicity; Phase change   Localisation; Solar evaporators; Thermal; Thermal energy management; Thermal localization; Water scarcity; Boron
 materials; Phase interfaces; Solar energy; Thermal Engineering; Balancing evaporation and condensation; Energy;   carbide; Economic and social effects; Evaporation
 Evaporation and condensation; Hydrophilic/hydrophobic; Hydrophilic/hydrophobic coating; Hydrophobic coatings;
 Interfacial engineering; Photo-thermal; Solar evaporators; Steam generation; Condensation; controlled study; electric   Abstract:
 potential; enthalpy; evaporation; fresh water; liquid; nonhuman; pharmaceutics; reduction (chemistry); review; solar
 energy; vapor; water; water vapor  Solar-driven interfacial evaporation represents a sustainable pathway to mitigate global water scarcity; however, its
        practical implementation is often constrained by the trade-off between high efficiency, structural complexity, and
 Abstract:  susceptibility to salt fouling. Herein, we developed a scalable, cost-effective solar evaporator fabricated from boron
        carbide (B4C) nanoparticles, which is anchored on a groove-engineered polyurethane (PU) foam within a polyvinyl
 Solar-driven steam generation (SSG) is an efficient process for converting solar energy into thermal energy,   alcohol (PVA) matrix, bridging the gap between efficiency and scalability. This cavity-inspired grooved structure
 demonstrating significant potential for industrial use. Recent progress in interfacial engineering, particularly   couples efficient photothermal conversion, local heat confinement without any solar concentrator, and fast water
 through innovations in photothermal layer design and condenser optimization, has enabled remarkable solar-  transport with effective hydrophilicity (zero contact angle). The effective heat localization realized in these grooved
 thermal conversion efficiencies at the air/liquid interface. This review systematically examines interfacial engineering   structures (42.16 °C) than plain structure (39.06 °C), as simulated through COMSOL heat transfer simulations. Under
 strategies for high-performance evaporators, emphasizing the critical role of hydrophilic/hydrophobic coatings   one-sun irradiation, the optimized evaporator achieves an evaporation rate of 1.55 kg m−2 h−1, a value increased
 in achieving sustainable water production. Furthermore, it evaluates condensing structures, comprehensively   by 28 % compared with plain structure systems (1.21 kg m−2 h−1) while maintaining stable performance across
 classifying condensers and their influence on freshwater yield. By analyzing key physical factors, including phase-  diverse aqueous environments, including seawater, river water, and industrial effluents (MO, MB, RhB) with varying
 change dynamics, vapor-liquid equilibrium, and enthalpy reduction strategies for photothermal materials (PTMs), as   salinity and pH. The system also exhibits exceptional antifouling characteristics, with >99 % salt rejection and > 98 %
 well as the harnessing of ambient energy for enhanced evaporation, this review offers a framework to elucidate the   removal of heavy metal ions (Pb2+, Cd2+). This work combines material innovation with structure design and pushes
 mechanisms of hydrophilic/hydrophobic coatings and identify potential breakthroughs under optimized conditions.   the development of robust, high-throughput solar evaporators for the real world for desalination and wastewater
 Finally, we discuss the prospective applications of SSG systems with advanced evaporators and condensers, alongside   treatment. The B4C@PU system thereby provides a green route for alleviating water scarcity by simultaneously
 the prevailing challenges in scalability and practical implementation.  solving the critical bottlenecks of density, cost, and salt fouling.


 Read the paper                                     Read the paper





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