Low-Grade Syngas Biomethanation in Continuous Reactors with Respect to Gas–Liquid Mass Transfer and Reactor Start-Up Strategy

Jiang, Bingyi; Zhang, Dongming; Hu, Xiao; Söderlind, Ulf; Paladino, Gabriela; Gamage, Shiromini; Hedenström, Erik; Zhang, Wennan; Arrigoni, Juan; Lundgren, Anders; Tuvesson, Malin; Yu, Cunjiang

doi:10.3390/fermentation9010038

Cited by 3 publications

(1 citation statement)

References 44 publications

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“…This gas contains H 2 , CO, and CO 2 as main components and smaller amounts of methane and short-chain hydrocarbons [102,103]. Several reports are found in the scientific literature regarding syngas conversion using pure and mixed microflora [104][105][106], along with specially selected mixtures of organisms for attaining the conversion of CO to methane [107][108][109]. The interest has further increased to develop technologies based on valorizing steel mill waste gases.…”

Section: Biological Conversion Of Hydrogen To Methane In Reactors Wit...mentioning

confidence: 99%

Biological Hydrogen Methanation with Carbon Dioxide Utilization: Methanation Acting as Mediator in the Hydrogen Economy

et al. 2023

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Hydrogen is one of the main energy carriers playing a prominent role in the future decarbonization of the economy. However, several aspects regarding the transport and storage of this gas are challenging. The intermediary conversion of hydrogen into high-density energy molecules may be a crucial step until technological conditions are ready to attain a significant reduction in fossil fuel use in transport and the industrial sector. The process of transforming hydrogen into methane by anaerobic digestion is reviewed, showing that this technology is a feasible option for facilitating hydrogen storage and transport. The manuscript focuses on the role of anaerobic digestion as a technology driver capable of fast adaptation to current energy needs. The use of thermophilic systems and reactors capable of increasing the contact between the H2-fuel and liquid phase demonstrated outstanding capabilities, attaining higher conversion rates and increasing methane productivity. Pressure is a relevant factor of the process, allowing for better hydrogen solubility and setting the basis for considering feasible underground hydrogen storage concomitant with biological methanation. This feature may allow the integration of sequestered carbon dioxide as a relevant substrate.

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Section: Biological Conversion Of Hydrogen To Methane In Reactors Wit...mentioning

confidence: 99%

Biological Hydrogen Methanation with Carbon Dioxide Utilization: Methanation Acting as Mediator in the Hydrogen Economy

et al. 2023

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Carbon monoxide conversion by anaerobic microbiome in a thermophilic trickle bed reactor

Ali,

Samadi,

Yde

et al. 2024

Biochemical Engineering Journal

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Strategies to overcome mass transfer limitations of hydrogen during anaerobic gaseous fermentations: A comprehensive review

Enriquez

Ahring

2023

Bioresource Technology

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Low-Grade Syngas Biomethanation in Continuous Reactors with Respect to Gas–Liquid Mass Transfer and Reactor Start-Up Strategy

Cited by 3 publications

References 44 publications

Biological Hydrogen Methanation with Carbon Dioxide Utilization: Methanation Acting as Mediator in the Hydrogen Economy

Biological Hydrogen Methanation with Carbon Dioxide Utilization: Methanation Acting as Mediator in the Hydrogen Economy

Carbon monoxide conversion by anaerobic microbiome in a thermophilic trickle bed reactor

Strategies to overcome mass transfer limitations of hydrogen during anaerobic gaseous fermentations: A comprehensive review

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