Youngsuk Nam2,Jeonghoon Han1,Seongjong Shin2,Seungtae Oh3,Heejae Hwang4,Dukhyun Choi5,Choongyeop Lee3
Korea Institute of Energy Research1,Korea Advanced Institute of Science and Technology2,Kyung Hee University3,Korea Institute of Science and Technology4,Sungkyunkwan University5
Youngsuk Nam2,Jeonghoon Han1,Seongjong Shin2,Seungtae Oh3,Heejae Hwang4,Dukhyun Choi5,Choongyeop Lee3
Korea Institute of Energy Research1,Korea Advanced Institute of Science and Technology2,Kyung Hee University3,Korea Institute of Science and Technology4,Sungkyunkwan University5
Recent studies on water-based pyroelectric generators (PyGs), which convert thermal energy to electrical energy, have focused on different operational modes like water evaporation, water stream, and droplet sliding. However, the development of sustainable, high-powered generators and comprehensive theoretical models has been limited. In response, our research introduces a superhydrophobic (SHPo) PyG, exploiting the characteristics of lead magnesium niobate-lead titanate (PMN-PT) coated with titanium dioxide nanoparticles. We analyzed power density by considering the phase transient temperature that maximizes the pyroelectric coefficient of PMN-PT, testing various Weber numbers and droplet diameters within a moderate operating temperature range of 40°C to 80°C. Considering the dynamic characteristics of water droplet on SHPo surfaces, we suggest the peak current model that can accurately predicting the actual peak current. Also, the maximum power density of 54.5 μW/cm<sup>2</sup> at a droplet diameter of 3.6 mm and a PMN-PT temperature of 80°C, a noteworthy improvement over 3 times higher than previous water-based PyGs. Our results enhance the understanding of the pyroelectric effect coupled with drop impact dynamics and outlines novel strategies for designing high-performance water-based PyGs.