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Analyzing and validating the performance of proton exchange membrane (PEM) fuel cells is a critical step towards advancing fuel cell technology for power generation and energy conversion. PEM fuel cells utilize electrocatalysts and fuel cell materials to convert chemical energy into electrical energy, and their efficiency and durability depend on the careful design and optimization of the fuel cell components, such as the membrane electrode assembly and the fuel cell stack. Electrochemical analysis is an important tool for evaluating PEM fuel cell performance, and researchers use a variety of techniques to analyze fuel cell voltage, current density, impedance, and catalyst activity. Modeling and testing of fuel cells is also necessary to optimize their design and operation for maximum efficiency and durability. PEM fuel cells have many potential applications, including in fuel cell vehicles and power systems, and the development of new diagnostic techniques and cost analysis tools is critical for their commercialization and widespread use. Research in fuel cell engineering and innovation has led to improvements in fuel cell efficiency and lifetime, as well as the development of new fuel cell manufacturing and fabrication methods. The use of PEM fuel cells in renewable and sustainable energy systems is a promising avenue for reducing carbon emissions and advancing clean energy technologies. Therefore, continued research and development in the field of PEM fuel cells is essential to realizing their full potential as a viable alternative to traditional fossil fuels.