Hydrogen Plasma Reduction for Steelmaking and Circular Economy
H2PlasmaRed published the 2nd peer-reviewed publication: In Situ Observation of Sustainable Hematite-Magnetite-Wustite-Iron Hydrogen Plasma Reduction
June 6, 2025
by DEC manager

H2PlasmaRed published the 2nd peer-reviewed publication: In Situ Observation of Sustainable Hematite-Magnetite-Wustite-Iron Hydrogen Plasma Reduction

We’re pleased to share H2PlasmaRed Horizon Europe’s second peer reviewed article publication by Henri Pauna, Isnaldi R. Souza Filho, Michael Kulse, Matic Jovičević-Klug, Hauke Springer, Marko Huttula, Timo Fabritius & Dierk Raabe  in the Metallurgical and Materials Transactions B: In Situ Observation of Sustainable Hematite–Magnetite–Wüstite–Iron Hydrogen Plasma Reduction.

The full article is available here: https://link.springer.com/article/10.1007/s11663-025-03610-y
 
Hydrogen plasma smelting reduction (HPSR) is an energy efficient, electrified, and fast process route to reduce not only iron ores but also thermally stable oxide materials, such as steelmaking sidestreams, waste, lean metallic ores, and metals with strong oxygen bonds. Both basic research of the underlying redox reaction mechanisms and upscaling and piloting of HPSR has gained significant momentum during the past decade, shedding light on reaction kinetics, hydrogen utilization, and process optimization.

Yet, many questions still remain unanswered, the most important of which are how the reduction actually works at the interface between the hydrogen plasma and the oxidic and metal melts and what the actual radical species distribution is at the interface. Here, we present for the first time an in situ observation series of hematite reduction to metallic iron with filtered plasma imaging and optical emission spectroscopy.

With the aid of plasma imaging and the optical spectra, the hematite, magnetite, wüstite, and both near-complete and complete metallization phases could be identified. The atomic hydrogen, iron, and aluminum species together with molecular optical emissions of FeO molecules were used to further analyze the process.

Here, we study specifically hematite reduction to metallic iron at 10 pct H2/90 pct Ar in 450 and 900 mbar, and at 20 pct H2/80 pct Ar in 450 mbar as a model system.