2020
DOI: 10.1002/er.6117
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Pure hydrogen production by steam‐iron process: The synergic effect of MnO 2 and Fe 2 O 3

Abstract: Summary In the energy transition from fossil to clean fuels, hydrogen plays a key role. Proton‐exchange membrane fuel cells (PEMFCs) represent the most promising hydrogen application, but they require a pure hydrogen stream (CO < 10 ppm). The steam iron process represents a technology for the production of pure H2, exploiting iron redox cycles. If renewable reducing agents are used, the process can be considered completely green. In this context, bio‐ethanol can be an interesting solution that is still not tho… Show more

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Cited by 15 publications
(5 citation statements)
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“…At temperature higher than 500 °C ethanol starts to decompose producing mainly H2, CO and solid carbon. In an authors' previous work, the thermal ethanol decomposition pathway was studied at 675 °C and atmospheric pressure [22]. Based on the results, ethanol can be completely decomposed into a gaseous mixture mainly constituted by syngas and methane, which undergoes cracking reaction becoming responsible for coke formation.…”
Section: Fe-based Particlesmentioning
confidence: 99%
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“…At temperature higher than 500 °C ethanol starts to decompose producing mainly H2, CO and solid carbon. In an authors' previous work, the thermal ethanol decomposition pathway was studied at 675 °C and atmospheric pressure [22]. Based on the results, ethanol can be completely decomposed into a gaseous mixture mainly constituted by syngas and methane, which undergoes cracking reaction becoming responsible for coke formation.…”
Section: Fe-based Particlesmentioning
confidence: 99%
“…In authors' previous work, pure H2 by 2 steps CLH is obtained using bioethanol as reducing agent and pure Fe2O3 as redox material. A relationship between the amount of ethanol fed in the reduction and the purity of H2 was demonstrated [22,23]. Specifically, if the complete reduction to Fe is avoided by monitoring the amount of ethanol fed, the lattice oxygen atoms of iron oxide are still able to convert solid carbon into CO and CO2, preventing its deposition and therefore guarantying a pure H2 stream in oxidation.…”
Section: Introductionmentioning
confidence: 99%
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“…The process lost relevance when H 2 could be produced more cheaply through steam reforming or water gas shi, 20 in the emerging petrochemical industry (1910 onwards). Recently, researchers' interest in this elegant process has been rekindled [21][22][23][24][25] due to the rise in the demand for CO-free H 2 as needed in fuel cells. Similarly, metal oxides enable efficient chemical looping combustion, which gained research interest due to the ease of CO 2 capture: [26][27][28][29][30] if a metal oxide is reduced using carbon-based fuel, the off-gas can be directly subjected to CO 2 capture without gas separation.…”
Section: Introductionmentioning
confidence: 99%
“…Among the broad variety of proposed metals, many excel in terms of reactivity if compared with Fe. 24,[31][32][33][34][35][36][37] Steinfeld et al, 16 however, recently provided an in-depth technical analysis conrming Fe as overall the most suitable metal for chemical looping H 2 storage and production if compared to Zn, Sn, Ge, W and Mo, in terms of reaction thermodynamics, H 2 storage density, resistance to sintering, safety and cost.…”
Section: Introductionmentioning
confidence: 99%