Green steel from red mud through climate-neutral hydrogen plasma reduction

Article

Jovicevic-Klug, Matic; Souza Filho, Isnaldi R.; Springer, Hauke; Adam, Christian; Raabe, Dierk

Max Planck Society; RWTH Aachen University; Federal Institute for Materials Research & Testing

Nature

0028-6999

10.1038/s41586-023-06901-z

2024-01-25

Red mud is the waste of bauxite refinement into alumina, the feedstock for aluminium production1. With about 180 million tonnes produced per year1, red mud has amassed to one of the largest environmentally hazardous waste products, with the staggering amount of 4 billion tonnes accumulated on a global scale1. Here we present how this red mud can be turned into valuable and sustainable feedstock for ironmaking using fossil-free hydrogen-plasma-based reduction, thus mitigating a part of the steel-related carbon dioxide emissions by making it available for the production of several hundred million tonnes of green steel. The process proceeds through rapid liquid-state reduction, chemical partitioning, as well as density-driven and viscosity-driven separation between metal and oxides. We show the underlying chemical reactions, pH-neutralization processes and phase transformations during this surprisingly simple and fast reduction method. The approach establishes a sustainable toxic-waste treatment from aluminium production through using red mud as feedstock to mitigate greenhouse gas emissions from steelmaking. Red mud is shown to yield green steel through fossil-free hydrogen-plasma-based reduction, a simple and fast method involving rapid liquid-state reduction, chemical partitioning, and density-driven and viscosity-driven separation.