Biogas process parameters—energetics and kinetics of secondary fermentations in methanogenic biomass degradation

Montag, Dominik; Schink, Bernhard

doi:10.1007/s00253-015-7069-0

Cited by 18 publications

(13 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Overloads often are related to acid accumulation (Figure 3), indicating an imbalance of microbial acid producers and consumers [40,63,68,69]. The underlying mechanism is based on different ways of obtaining energy and consequently on different growth rates: a thermodynamically more favorable energy production results in faster growth rates of the microorganisms [70][71][72][73].…”

Section: Overload Of the Microbial Degradation Potentialmentioning

confidence: 99%

“…While the energy balance of most hydrolytic and acidogenic reactions is negative -meaning a direct energy gain for the microorganisms-the reactions of acid-degrading microorganisms are thermodynamically unfavorable and require more energy than they yield [70,71,74]. Acid-degrading microorganisms often live in syntrophy with hydrogen scavengers, in the biogas process ideally hydrogenotrophic archaea, due to the fact that the conversion of most fatty acids is only possible via the formation of hydrogen (H 2 ).…”

Section: Overload Of the Microbial Degradation Potentialmentioning

confidence: 99%

See 1 more Smart Citation

Process Disturbances in Agricultural Biogas Production—Causes, Mechanisms and Effects on the Biogas Microbiome: A Review

2019

View full text Add to dashboard Cite

Disturbances of the anaerobic digestion process reduce the economic and environmental performance of biogas systems. A better understanding of the highly complex process is of crucial importance in order to avoid disturbances. This review defines process disturbances as significant changes in the functionality within the microbial community leading to unacceptable and severe decreases in biogas production and requiring an active counteraction to be overcome. The main types of process disturbances in agricultural biogas production are classified as unfavorable process temperatures, fluctuations in the availability of macro- and micronutrients (feedstock variability), overload of the microbial degradation potential, process-related accumulation of inhibiting metabolites such as hydrogen (H2), ammonium/ammonia (NH4+/NH3) or hydrogen sulphide (H2S) and inhibition by other organic and inorganic toxicants. Causes, mechanisms and effects on the biogas microbiome are discussed. The need for a knowledge-based microbiome management to ensure a stable and efficient production of biogas with low susceptibility to disturbances is derived and an outlook on potential future process monitoring and control by means of microbial indicators is provided.

show abstract

Section: Overload Of the Microbial Degradation Potentialmentioning

confidence: 99%

Section: Overload Of the Microbial Degradation Potentialmentioning

confidence: 99%

Process Disturbances in Agricultural Biogas Production—Causes, Mechanisms and Effects on the Biogas Microbiome: A Review

2019

View full text Add to dashboard Cite

show abstract

“…The supernatant was used directly without acidification for analysis of soluble compounds. Short-chain fatty acids were measured using a Shimadzu Prominence high-performance liquid chromatograph equipped with an Aminex HPX87H column, a photo diode array detector, and a trace sensitive method for organic acids (26). pH measurement was done with a potentiometric electrode in the supernatant of the centrifugation step.…”

Section: Methodsmentioning

confidence: 99%

“…Sulfate reducers compete for available hydrogen or formate as well, but only if sufficient sulfate is available (24,25). Beyond experiments with isolated cultures, several studies have tried to assess the energetic situation of secondary fermentations and methane formation in the past by measuring pool sizes of fermentation intermediates, including hydrogen partial pressures in situ, both in natural sediments and in technical settings, such as sewage sludge digesters or biogas reactors (26)(27)(28)(29)(30)(31)(32).…”

Section: Importancementioning

confidence: 99%

“…Only recently have techniques been developed that allow measurement of formate in the micromolar range in environmental samples, even in the presence of large amounts of complex organic matter such as, e.g., humic compounds (26,27). In the present study, the importance of formate as an alternative electron shuttle in methanogenic biomass degradation was investigated in sediments of the oligotrophic Lake Constance in southern Germany, focusing on the energetic limitations of the transformation processes involved.…”

Section: Importancementioning

confidence: 99%

See 1 more Smart Citation

Formate and Hydrogen as Electron Shuttles in Terminal Fermentations in an Oligotrophic Freshwater Lake Sediment

Montag

Schink

2018

Appl Environ Microbiol

Self Cite

View full text Add to dashboard Cite

The energetic situation of terminal fermentations in methanogenesis was analyzed by pool size determinations in sediment cores taken in the oligotrophic Lake Constance, Germany. Distribution profiles of fermentation intermediates and products were measured at three different water depths (2, 10, and 80 m). Methane concentrations were constant below 10 cm of sediment depth. Within the methanogenic zone, concentrations of formate, acetate, propionate, and butyrate varied between 1 and 40 μM, and hydrogen was between 0.5 and 5 Pa. From the distribution profiles of the fermentation intermediates, Gibbs free energy changes for their interconversion were calculated. Pool sizes of formate and hydrogen were energetically nearly equivalent, with -5 ± 5 kJ per mol difference of free energy change (ΔG) for a hypothetical conversion of formate to hydrogen plus CO The ΔG values for conversion of fatty acids to methanogenic substrates and their further conversion to methane and CO were calculated with hydrogen and with formate as intermediates. Syntrophic propionate oxidation reached energetic equilibrium with formate as the sole electron carrier but was sufficiently exergonic if at least some of the electrons were transferred via hydrogen. The energetic consequences of formate versus hydrogen transfer in secondary and methanogenic fermentations indicate that both carrier systems are probably used simultaneously to optimize the energy yields for the partners involved. In the terminal steps of methane formation in freshwater lake sediments, fermenting bacteria cooperate syntrophically with methanogens and homoacetogens at minimum energy increments via interspecies electron transfer. The energy yields of the partner organisms in these cooperations have so far been calculated based mainly on hydrogen partial pressures. In the present study, we also analyzed pools of formate as an alternative electron carrier in sediment cores of an oligotrophic lake. The formate and hydrogen pools appeared to be energetically nearly equivalent and are likely to be used simultaneously for interspecies electron transfer. Calculations of reaction energies of the partners involved suggest that propionate degradation may also proceed through the pathway, which converts propionate via butyrate and acetate to three acetate residues, thus circumventing one energetically difficult fatty acid oxidation step.

show abstract

Biogas Production: Microbiology and Technology

Schnürer

2016

Advances in Biochemical Engineering/Biotechnology

101

View full text Add to dashboard Cite

Biogas, containing energy-rich methane, is produced by microbial decomposition of organic material under anaerobic conditions. Under controlled conditions, this process can be used for the production of energy and a nutrient-rich residue suitable for use as a fertilising agent. The biogas can be used for production of heat, electricity or vehicle fuel. Different substrates can be used in the process and, depending on substrate character, various reactor technologies are available. The microbiological process leading to methane production is complex and involves many different types of microorganisms, often operating in close relationships because of the limited amount of energy available for growth. The microbial community structure is shaped by the incoming material, but also by operating parameters such as process temperature. Factors leading to an imbalance in the microbial community can result in process instability or even complete process failure. To ensure stable operation, different key parameters, such as levels of degradation intermediates and gas quality, are often monitored. Despite the fact that the anaerobic digestion process has long been used for industrial production of biogas, many questions need still to be resolved to achieve optimal management and gas yields and to exploit the great energy and nutrient potential available in waste material. This chapter discusses the different aspects that need to be taken into consideration to achieve optimal degradation and gas production, with particular focus on operation management and microbiology.

show abstract

Biogas process parameters—energetics and kinetics of secondary fermentations in methanogenic biomass degradation

Cited by 18 publications

References 48 publications

Process Disturbances in Agricultural Biogas Production—Causes, Mechanisms and Effects on the Biogas Microbiome: A Review

Process Disturbances in Agricultural Biogas Production—Causes, Mechanisms and Effects on the Biogas Microbiome: A Review

Formate and Hydrogen as Electron Shuttles in Terminal Fermentations in an Oligotrophic Freshwater Lake Sediment

Biogas Production: Microbiology and Technology

Contact Info

Product

Resources

About