The microbiology of Power-to-X applications

Logroño, Washington; Kleinsteuber, Sabine; Kretzschmar, Jörg; Vrieze, Jo De; Nikolausz, Marcell

doi:10.1093/femsre/fuad013

Cited by 5 publications

(4 citation statements)

References 285 publications

(287 reference statements)

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“…Based on a Power-to-X concept we calculated the gross electricity demand for the potential production of carbon-based fuels, plastics, and food with the following assumptions: electrochemical reduction of CO 2 to formate is taken as the primary step, assuming an electrical energy demand of 3.40 MWh/t formate 60 , 61 . Further reduction of carbon in the cellular metabolism is accounted for by partial oxidation of formate to provide reduction equivalents on a stoichiometric basis.…”

Section: Products That Can Be Made From C1 Carbon Sourcesmentioning

confidence: 99%

The potential of CO2-based production cycles in biotechnology to fight the climate crisis

Bachleitner,

Ata,

Mattanovich

2023

Nat Commun

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Rising CO2 emissions have pushed scientists to develop new technologies for a more sustainable bio-based economy. Microbial conversion of CO2 and CO2-derived carbon substrates into valuable compounds can contribute to carbon neutrality and sustainability. Here, we discuss the potential of C1 carbon sources as raw materials to produce energy, materials, and food and feed using microbial cell factories. We provide an overview of potential microbes, natural and synthetic C1 utilization pathways, and compare their metabolic driving forces. Finally, we sketch a future in which C1 substrates replace traditional feedstocks and we evaluate the costs associated with such an endeavor.

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Section: Products That Can Be Made From C1 Carbon Sourcesmentioning

confidence: 99%

The potential of CO2-based production cycles in biotechnology to fight the climate crisis

Bachleitner,

Ata,

Mattanovich

2023

Nat Commun

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“…In contrast to bacteria and yeasts, archaea are uncommon in biotechnological applications, apart from the central role of methanogenic archaea in producing biogas from organic waste streams. However, this anaerobic digestion process relies on complex microbial consortia dominated by bacteria (De Vrieze and Verstraete, 2016 ), whereas pure culture applications of methanogens in industrial scale are restricted to the biomethanation of hydrogen in Power-to-Gas approaches (Logroño et al, 2023 ). Carr and Buan review the opportunities for archaeal bioproducts beyond methane and describe how the unique and highly efficient metabolism of methanogens can be harnessed for the bioproduction of terpenes and future applications making use of synthetic biology.…”

Section: Other Topicsmentioning

confidence: 99%

Editorial: Women in microbial physiology and metabolism: 2022

Lorca

Kleinsteuber

2023

Front. Microbiol.

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“…Methanation can occur directly in a biogas plant by injecting hydrogen, called in situ methanation. However, in situ methanation can seriously inhibit the digestion of the biogas substrate if the hydrogen flow is too high [14,15]. When biomethanation is performed in a separate reactor that is fed with hydrogen and a carbon dioxide source, it is called ex situ methanation.…”

Section: Introductionmentioning

confidence: 99%

“…When biomethanation is performed in a separate reactor that is fed with hydrogen and a carbon dioxide source, it is called ex situ methanation. Ex situ methanation is easier to operate and can achieve higher methane production rates than in situ methanation [15,16].…”

Section: Introductionmentioning

confidence: 99%

Design and Construction of a New Reactor for Flexible Biomethanation of Hydrogen

Hoffstadt,

Cheenakula,

Nikolausz

et al. 2023

Fermentation

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The increasing share of renewable electricity in the grid drives the need for sufficient storage capacity. Especially for seasonal storage, power-to-gas can be a promising approach. Biologically produced methane from hydrogen produced from surplus electricity can be used to substitute natural gas in the existing infrastructure. Current reactor types are not or are poorly optimized for flexible methanation. Therefore, this work proposes a new reactor type with a plug flow reactor (PFR) design. Simulations in COMSOL Multiphysics ® showed promising properties for operation in laminar flow. An experiment was conducted to support the simulation results and to determine the gas fraction of the novel reactor, which was measured to be 29%. Based on these simulations and experimental results, the reactor was constructed as a 14 m long, 50 mm diameter tube with a meandering orientation. Data processing was established, and a step experiment was performed. In addition, a kLa of 1 h−1 was determined. The results revealed that the experimental outcomes of the type of flow and gas fractions are in line with the theoretical simulation. The new design shows promising properties for flexible methanation and will be tested.

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The microbiology of Power-to-X applications

Cited by 5 publications

References 285 publications

The potential of CO2-based production cycles in biotechnology to fight the climate crisis

The potential of CO2-based production cycles in biotechnology to fight the climate crisis

Editorial: Women in microbial physiology and metabolism: 2022

Design and Construction of a New Reactor for Flexible Biomethanation of Hydrogen

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