2026-03-102026-03-10https://hdl.handle.net/11420/61957BlueMat aims to revolutionize hydrovoltaics by developing next-generation hydrovoltaic material technologies. Our goal within D3 is to create high-performance, multiscale, porous materials and innovative hydrovoltaic device architectures to efficiently harness electrical energy from humidity variations, imbibition and drying cycles. We will systematically evaluate their energy conversion performance under varying humidity levels, temperatures, and operating conditions. Our research will focus on reducing imbibition–drying cycle times while enhancing energy output by leveraging humidity variations and low-grade waste heat. This interdisciplinary program aims to advance hydrovoltaics through cutting-edge experimentation, addressing key challenges, and unlocking new opportunities for sustainable energy generation from ambient environmental sources. We will develop highly adapted material architectures to optimize power, addressing issues like minimum friction, salt crystallization upon drying, or evaporation using aqueous electrolytes or water itself. The efforts in D3 aim to improve energy conversion efficiency, durability, and scalability of hydrovoltaic applications, paving the way for widespread deployment in diverse environmental settings. The key scientific questions include: How can we exploit novel hydrovoltaic mechanisms to generate energy from cyclic imbibition and desiccation of electrolyte-infused porous media? How do non-equilibrium fluid dynamics, surface chemistry, open-circuit potential, and other fundamental factors, including the interaction of imbibition and drying influenced by pore characteristics and external stimuli, affect the proposed scheme? How can we optimize the performance of the hydrovoltaic scheme using concepts like hierarchically porous electrodes and adaptive pore wall coatings?