The global drive to significantly reduce greenhouse gas emissions is pushing industries to adopt hydrogen as both a reducing agent and fuel for high-temperature processes. While some knowledge exists on the impact of hydrogen-rich reducing atmospheres on refractory linings from established industrial processes like glass manufacturing, ammonia or syngas synthesis, and natural gas-based direct reduced iron (DRI), the use of hydrogen as a reductant for iron production is gaining traction as a key solution for the steel industry's transition to net-zero emissions. This involves using hydrogen in small percentages to replace coal in blast furnaces and, more significantly, substituting natural gas with hydrogen in the DRI process, potentially up to 100 %. Moreover, the growing demand for fossil-free fuels has spurred the development of innovative and optimized hydrogen and syngas generation technologies.While new and established processes differ in their specific conditions, there is a limited amount of information available in the literature about the long-term effects of hydrogen-rich atmospheres on refractories. Recent studies have yielded contradictory results compared to earlier research, making it challenging to discern myths from facts and accurately assess the performance and lifespan of refractory linings in these environments. This presentation aims to share fact-based findings from ongoing research and our experience in various industries, providing insights into the impact of hydrogen on refractory linings as a function of process conditions and testing parameters.