Abstract
Presently, Iron is produced from iron ores by using carbon from coal. The production process is consisting of many stages. The involvement of multi-stages needs high capital investments, large-scale equipments, and produces large amounts of carbon dioxide (CO2) responsible for environmental pollution. There have been significant efforts to replace carbon with hydrogen (H2). Although H2 is the strongest reductant, it still also has thermodynamic and kinetic limitations. However, these thermodynamic and kinetic limitations could be removed by hydrogen plasma (HP). HP comprises rovibrationally excited molecular, atomic, and ionic states of hydrogen. All of them contribute to thermodynamic advantage by making the Gibbs standard free energy more negative, which makes the reduction of iron oxides feasible at low temperatures. Apart from the thermodynamic advantage, these excited species increase the internal energy of HP, which reduces the activation energy, thereby making the reduction easier and faster. Apart from the thermodynamic and kinetic advantage of HP, the byproduct of the reaction is environmentally benign water. This review discusses the physics and chemistry of iron ore reduction using HP, emphasizing the solid-state reduction of iron ore. HP reduction of iron ore is a high potential and attractive reduction process.
Highlights
Iron is produced from medium or highgrade iron ore by using carbon; a process called carbothermic reduction
The present carbothermic reduction process consists of many unit steps/processes like coke-making, pelletization, sintering, etc
The thermodynamic advantages of the excited species in hydrogen plasma (HP) have been illustrated in the Ellingham diagram (Fig. 2), which has been explained here
Summary
Iron is produced from medium or highgrade iron ore by using carbon; a process called carbothermic reduction. In addition to lower consumption and the ease of availability, H2 possesses many technical advantages: (a) CO and CO2 are avoided because the product gases are mixtures of H2O and H2, (b) the reduction rate becomes faster because of the small size of H2, (c) avoids the carbon content in the produced Iron, (d) elimination of costly and polluting cokemaking step, (e) the consumption of energy decreases by 57 %, (f) the emission of CO2 decreases by 96 pct These advantages mainly come from eliminating the problematic unit steps/processes like cokemaking and sintering or pelletization [22]. Due to the high temperature and excited active hydrogen species, thermal HP provides thermodynamic feasibility and quicker kinetics, respectively This unique combination permits single-step iron production without any carbon footprint. It is the reduction of iron ore by HP, discussed below
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