The ITER project is pioneering fusion energy research with the introduction of an innovative boronization system. This system aims to enhance plasma stability by applying a thin boron layer to surfaces, buffering the plasma from impurities and improving efficiency. The project utilizes diborane, a compound of hydrogen and boron, to deposit boron through a glow-discharge-assisted method within the tokamak. International collaboration with experts from Germany, France, and China has been vital in overcoming design challenges and ensuring optimal boron distribution. Safety measures have been implemented to address the hazardous nature of diborane, including secure storage and neutralization plans. Operational questions such as the frequency of boronization applications have been addressed, with studies suggesting optimal intervals for application. Looking ahead, with the boronization system scheduled for installation in 2028, ITER is on track to advance fusion energy research and contribute to sustainable energy solutions globally. The article emphasizes the significance of international collaboration and innovative technologies in driving progress in fusion energy research and raises questions about the future possibilities in the quest for sustainable energy alternatives.