The influence of temperature on the performance of photovoltaic (PV) panels is a critical consideration in harnessing the potential of solar energy technology. This compilation of research papers explores the multifaceted impact of operating temperature on PV systems and the utilization of cooling technologies to enhance their efficiency. The studies consistently emphasize the detrimental effects of elevated temperatures on PV cells and modules and investigate various aspects, including temperature-dependent parameters, real-world environmental conditions, geographical distribution, and mitigation strategies. Accurate modeling and location-specific considerations are underscored as vital for optimizing PV system efficiency. As the world embraces renewable energy and sustainability, the insights presented in these papers offer valuable contributions to advancing solar power technology for a more sustainable future. Furthermore, this collection emphasizes the significance of addressing temperature-related efficiency losses in PV panels and the potential for cooling solutions to improve performance. Various cooling methods, such as air cooling, water cooling, evaporative cooling, and phase change materials, are explored to mitigate the impact of high operating temperatures on PV systems. Integrated systems that combine cleaning and cooling mechanisms to address both soiling and heating issues are proposed. Environmental and economic considerations are pivotal in assessing the feasibility of implementing cooling solutions in different settings. These studies collectively stress the need for effective cooling technologies, especially in regions with extreme temperatures and intense solar radiation, to unlock the full potential of PV systems. Researchers, engineers, and policymakers working in the field of renewable energy will find these findings valuable for advancing the efficient utilization of solar power