Fischer-Tropsch products from biomass-derived syngas and renewable hydrogen

Gruber, Hannes; Groß, P.; Rauch, Reinhard; Reichhold, Alexander; Zweiler, Richard; Aichernig, Christian; Müller, Stefan; Ataimisch, Nabeel; Hofbauer, Hermann

doi:10.1007/s13399-019-00459-5

Cited by 59 publications

(41 citation statements)

References 47 publications

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“…422 Instead of storing excess electricity in H 2 storage facilities after electrolysis, current work indicates that the direct utilisation by adapting the H 2 /CO ratio can be used while increasing the productivity and simultaneously keeping the product distribution range almost unchanged. 424 As already mentioned, the product distribution strongly depends on the contact time between the catalyst and educt gas. Therefore increasing GHSV result in a decrease of the CO conversion as well as the C 5+ .…”

Section: View Article Onlinementioning

confidence: 93%

Power-to-liquidviasynthesis of methanol, DME or Fischer–Tropsch-fuels: a review

Dieterich

Buttler

Hánel

et al. 2020

Energy Environ. Sci.

424

246

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Section: View Article Onlinementioning

confidence: 93%

Power-to-liquidviasynthesis of methanol, DME or Fischer–Tropsch-fuels: a review

Dieterich

Buttler

Hánel

et al. 2020

Energy Environ. Sci.

424

246

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“…As shown in Figure 2, the GTJ route is comprised of two different processes, namely, biomass gasification to syngas (H 2 /CO), followed by Fischer-Tropsch conversion of this syngas into jet fuel hydrocarbons [52]. Gasification is a well-developed technology that allows conversion of virtually any carbon source (natural gas, coal, biomass) into a mixture of gaseous species (e.g., CO, H 2 , CO 2 , CH 4 ) by applying a treatment at high temperatures under a carefully controlled oxidizing atmosphere (e.g., air, steam, oxygen).…”

Section: Gas To Jet Fuelsmentioning

confidence: 99%

Catalytic Production of Jet Fuels from Biomass

Díaz‐Pérez

Serrano‐Ruiz

2020

Molecules

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Concerns about depleting fossil fuels and global warming effects are pushing our society to search for new renewable sources of energy with the potential to substitute coal, natural gas, and petroleum. In this sense, biomass, the only renewable source of carbon available on Earth, is the perfect replacement for petroleum in producing renewable fuels. The aviation sector is responsible for a significant fraction of greenhouse gas emissions, and two billion barrels of petroleum are being consumed annually to produce the jet fuels required to transport people and goods around the world. Governments are pushing directives to replace fossil fuel-derived jet fuels with those derived from biomass. The present mini review is aimed to summarize the main technologies available today for converting biomass into liquid hydrocarbon fuels with a molecular weight and structure suitable for being used as aviation fuels. Particular emphasis will be placed on those routes involving heterogeneous catalysts.

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“…Furthermore, its intermediate location within the overall production chain, from feedstocks to chemicals or fuels, allows for existing downstream processes to be run without any substantial modifications and, simultaneously, to benefit from a sustainable feed stream. Due to the fact that syngas can be readily converted into liquid fuels, i.e., via Fischer-Tropsch synthesis (Gruber et al, 2019), it plays a crucial role in decarbonizing the transportation system.…”

Section: Introductionmentioning

confidence: 99%

Mixed-Integer Linear Programming (MILP) Approach for the Synthesis of Efficient Power-to-Syngas Processes

2020

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Within the context of energy transition scenarios toward renewable resources, superstructure optimization is implemented for the synthesis of sustainable and efficient Power-to-Syngas processes. A large number of reactors (reverse water-gas-shift, steam reforming, dry reforming, tri-reforming, methane partial oxidation reactor, and water electrolyzer) and separators (PSA, TSA, cryogenics, membranes, and gas-liquid scrubbing) are included within a single MILP framework, accounting for typical operating conditions of each process-unit, under the specified simplifying assumptions. Power is minimized in the context of sustainable feedstocks: water and biogas or carbon dioxide from direct air-capture. The objective function adds the thermal to the electrical contribution to the total power, the latter being weighted by a pseudo-price of null (i.e., sustainable, in-house electricity production), or unitary value (i.e., electricity purchased, possibly generated from non-sustainable sources). Simultaneous operations of multiple reactor technologies are allowed to identify possible synergies. With biogas and null value of the pseudo-price, the results identify plant configurations mainly run via electricity, which constitutes up to 97% of the total power for cooperating partial oxidation of methane and water electrolysis. Alternatively, lower total demands are attained at the expenses of thermal duty when electricity is penalized: the endothermic reactors are operated. With carbon dioxide, the total power demand dramatically increases due to the large consumptions of direct-air capture and water electrolysis. The resulting topologies always favor membrane separation, adsorption, and cryogenics over absorption technologies.

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Fischer-Tropsch products from biomass-derived syngas and renewable hydrogen

Cited by 59 publications

References 47 publications

Power-to-liquidviasynthesis of methanol, DME or Fischer–Tropsch-fuels: a review

Power-to-liquidviasynthesis of methanol, DME or Fischer–Tropsch-fuels: a review

Catalytic Production of Jet Fuels from Biomass

Mixed-Integer Linear Programming (MILP) Approach for the Synthesis of Efficient Power-to-Syngas Processes

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