Unraveling the thermodynamics and mechanism behind the lowering of reduction temperatures in oxide mixtures

Abstract

Hydrogen-based direct reduction offers a sustainable pathway to decarbonize the metal production industry. However, stable metal oxides, like Cr2O3, are notoriously difficult to reduce, requiring extremely high temperatures (above 1300 ). Herein, we show how reducing mixed oxides can be leveraged to lower hydrogen-based reduction temperatures of stable oxides and produce alloys in a single process. Using a newly developed thermodynamic framework, we predict the precise conditions (oxygen partial pressure, temperature, and oxide composition) needed for co-reduction. We showcase this approach by reducing Cr2O3 mixed with Fe2O3 at 1100 , significantly lowering reduction temperatures (by ≥200 ). Our model and post-reduction atom probe tomography analysis elucidate that the temperature-lowering effect is driven by the lower chemical activity of Cr in the metallic phase. This strategy achieves low-temperature co-reduction of mixed oxides, dramatically reducing energy consumption and CO2 emissions, while unlocking transformative pathways toward sustainable alloy design.

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