Solar hydrogen production with cerium oxides thermochemical cycle

Binotti, Marco; Marcoberardino, Gioele Di; Biassoni, Mauro; Manzolini, Giampaolo

doi:10.1063/1.4984459

Cited by 10 publications

(3 citation statements)

References 21 publications

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“…Conventional fuel processors include a steam or autothermal reformer, followed by one or two stages of water gas shift (WGS) to enhance hydrogen concentration in the reformate stream, and a pressure swing adsorption unit for hydrogen separation and purification. There are also some studies on other non-conventional processes for hydrogen production from methane, such us solar reforming, thermal plasma reforming, and catalytic decomposition [6,[10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Green Hydrogen Production from Raw Biogas: A Techno-Economic Investigation of Conventional Processes Using Pressure Swing Adsorption Unit

et al. 2018

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This paper discusses the techno-economic assessment of hydrogen production from biogas with conventional systems. The work is part of the European project BIONICO, whose purpose is to develop and test a membrane reactor (MR) for hydrogen production from biogas. Within the BIONICO project, steam reforming (SR) and autothermal reforming (ATR), have been identified as well-known technologies for hydrogen production from biogas. Two biogases were examined: one produced by landfill and the other one by anaerobic digester. The purification unit required in the conventional plants has been studied and modeled in detail, using Aspen Adsorption. A pressure swing adsorption system (PSA) with two and four beds and a vacuum PSA (VPSA) made of four beds are compared. VPSA operates at sub-atmospheric pressure, thus increasing the recovery: results of the simulations show that the performances strongly depend on the design choices and on the gas feeding the purification unit. The best purity and recovery values were obtained with the VPSA system, which achieves a recovery between 50% and 60% at a vacuum pressure of 0.1 bar and a hydrogen purity of 99.999%. The SR and ATR plants were designed in Aspen Plus, integrating the studied VPSA model, and analyzing the behavior of the systems at the variation of the pressure and the type of input biogas. The SR system achieves a maximum efficiency, calculated on the LHV, of 52% at 12 bar, while the ATR of 28% at 18 bar. The economic analysis determined a hydrogen production cost of around 5 €/kg of hydrogen for the SR case.

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Section: Introductionmentioning

confidence: 99%

Green Hydrogen Production from Raw Biogas: A Techno-Economic Investigation of Conventional Processes Using Pressure Swing Adsorption Unit

et al. 2018

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“…Steam or autothermal reformers have conventional fuel processors, composed of 1 or 2 stages for changing the water gas to increase the hydrogen concentration in the reformed stream, as well as a pressure swing adsorber to separate and purify H 2 . Alternative, unconventional techniques used to produce hydrogen from CH 4 include solar or thermal plasma reforming as well as catalytic splitting [87,91,92]. H 2 can also be generated via steam reforming of biogas over a wide temperature range (from 600 to 1000 • C), a region of endergonic reversible reactions that often involve events of combined catalysis.…”

Section: Green Hydrogen Productionmentioning

confidence: 99%

Use of Hydrogen as Fuel: A Trend of the 21st Century

Farias

Barreiros²,

Silva

et al. 2022

Energies

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The unbridled use of fossil fuels is a serious problem that has become increasingly evident over the years. As such fuels contribute considerably to environmental pollution, there is a need to find new, sustainable sources of energy with low emissions of greenhouse gases. Climate change poses a substantial challenge for the scientific community. Thus, the use of renewable energy through technologies that offer maximum efficiency with minimal pollution and carbon emissions has become a major goal. Technology related to the use of hydrogen as a fuel is one of the most promising solutions for future systems of clean energy. The aim of the present review was to provide an overview of elements related to the potential use of hydrogen as an alternative energy source, considering its specific chemical and physical characteristics as well as prospects for an increase in the participation of hydrogen fuel in the world energy matrix.

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“…Unlike prior hydrocarbons-to-hydrogen chemistries that produce greenhouse gases [1,2], catalytic methane cracking makes solid carbon for sequestration or reuse [3]. When driven with solar heat, this reaction can generate greenhouse-neutral hydrogen fuel from carbonaceous feedstocks, a transitional technology towards fully sustainable infrastructure [4][5][6][7][8][9][10][11][12][13]. Figure 1 shows the concept, wherein a macroscopic reactor harbors microscopic reaction.…”

Section: Introductionmentioning

confidence: 99%

Reversible Molten Catalytic Methane Cracking Applied to Commercial Solar-Thermal Receivers

et al. 2020

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When driven by sunlight, molten catalytic methane cracking can produce clean hydrogen fuel from natural gas without greenhouse emissions. To design solar methane crackers, a canonical plug flow reactor model was developed that spanned industrially relevant temperatures and pressures (1150–1350 Kelvin and 2–200 atmospheres). This model was then validated against published methane cracking data and used to screen power tower and beam-down reactor designs based on “Solar Two,” a renewables technology demonstrator from the 1990s. Overall, catalytic molten methane cracking is likely feasible in commercial beam-down solar reactors, but not power towers. The best beam-down reactor design was 9% efficient in the capture of sunlight as fungible hydrogen fuel, which approaches photovoltaic efficiencies. Conversely, the best discovered tower methane cracker was only 1.7% efficient. Thus, a beam-down reactor is likely tractable for solar methane cracking, whereas power tower configurations appear infeasible. However, the best simulated commercial reactors were heat transfer limited, not reaction limited. Efficiencies could be higher if heat bottlenecks are removed from solar methane cracker designs. This work sets benchmark conditions and performance for future solar reactor improvement via design innovation and multiphysics simulation.

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Solar hydrogen production with cerium oxides thermochemical cycle

Cited by 10 publications

References 21 publications

Green Hydrogen Production from Raw Biogas: A Techno-Economic Investigation of Conventional Processes Using Pressure Swing Adsorption Unit

Green Hydrogen Production from Raw Biogas: A Techno-Economic Investigation of Conventional Processes Using Pressure Swing Adsorption Unit

Use of Hydrogen as Fuel: A Trend of the 21st Century

Reversible Molten Catalytic Methane Cracking Applied to Commercial Solar-Thermal Receivers

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