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Fermentative hydrogen production is a novel aspect of anaerobic digestion. The main advantage of hydrogen is that it is a clean and renewable energy source/carrier with high specifi c heat of combustion and no contribution to the Greenhouse effect, and can be used in many industrial applications. This review discusses fermentative hydrogen production from various points of view. First, the theoretical principles of the biological processes taking place in hydrogen production, as well as the organisms responsible for this process, are described. Second, practical aspects of fermentative hydrogen production are overviewed. Suitable conditions for the hydrogen-producers (pH and temperature), suitable substrates for hydrogen production and applicable reactor designs are discussed.Finally, the challenges faced by fermentative hydrogen production are discussed. Current research directions are listed together with the most important problems currently constraining full-scale application.

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Metal supplementation to UASB bioreactors: from cell-metal interactions to full-scale application

Fermoso

Bartacek

Jansen

et al. 2009

Science of The Total Environment

123

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Acidification of methanol‐fed anaerobic granular sludge bioreactors by cobalt deprivation: Induction and microbial community dynamics

Fermoso¹,

Collins²,

Bartacek³

et al. 2007

Biotech & Bioengineering

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The acidification of mesophilic (30 degrees C) methanol-fed upflow anaerobic sludge bed (UASB) reactors induced by cobalt deprivation from the influent was investigated by coupling the reactor performance (pH 7.0; organic loading rate 4.5 g COD . L(-1) . d(-1)) to the microbial ecology of the bioreactor sludge. The latter was investigated by specific methanogenic activity (SMA) measurements and fluorescence in situ hybridization (FISH) to quantify the abundance of key organisms over time. This study hypothesized that under cobalt limiting conditions, the SMA on methanol of the sludge gradually decreases, which ultimately results in methanol accumulation in the reactor effluent. Once the methanol accumulation surpasses a threshold value (about 8.5 mM for the sludge investigated), reactor acidification occurs because acetogens outcompete methylothrophic methanogens at these elevated methanol concentrations. Methanogens present in granular sludge at the time of the acidification do not use methanol as the direct substrate and are unable to degrade acetate. Methylotrophic/acetoclastic methanogenic activity was found to be lost within 10 days of reactor operation, coinciding with the disappearance of the Methanosarcina population. The loss of SMA on methanol can thus be used as an accurate parameter to predict reactor acidification of methanol-fed UASB reactors operating under cobalt limiting conditions.

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Treatment of acid mine drainage by forward osmosis: Heavy metal rejection and reverse flux of draw solution constituents

Vital

Bartacek

Ortega-Bravo

et al. 2018

Chemical Engineering Journal

127

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Microaeration for hydrogen sulfide removal in UASB reactor

Krayzelova

Bartacek

Kolesárová

et al. 2014

Bioresource Technology

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Removal of H2S by a continuous microalgae-based photosynthetic biogas upgrading process

Meier

Stara

Bartacek

et al. 2018

Process Safety and Environmental Protection

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Potentials and limits of anaerobic digestion of sewage sludge: Energy self-sufficient municipal wastewater treatment plant?

Jenı́ček

Bartacek

Kutil

et al. 2012

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Anaerobic digestion is the only energy-positive technology widely used in wastewater treatment. Full-scale data prove that the anaerobic digestion of sewage sludge can produce biogas that covers a substantial amount of the energy consumption of a wastewater treatment plant (WWTP). In this paper, we discuss possibilities for improving the digestion efficiency and biogas production from sewage sludge. Typical specific energy consumptions of municipal WWTPs per population equivalent are compared with the potential specific production of biogas to find the required/optimal digestion efficiency. Examples of technological measures to achieve such efficiency are presented. Our findings show that even a municipal WWTP with secondary biological treatment located in a moderate climate can come close to energy self-sufficiency. However, they also show that such self-sufficiency is dependent on: (i) the strict optimization of the total energy consumption of the plant, and (ii) an increase in the specific biogas production from sewage sludge to values around 600 L per kg of supplied volatile solids.

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Jan Bartacek

Microaeration for hydrogen sulfide removal during anaerobic treatment: a review

Developments and constraints in fermentative hydrogen production

Metal supplementation to UASB bioreactors: from cell-metal interactions to full-scale application

Acidification of methanol‐fed anaerobic granular sludge bioreactors by cobalt deprivation: Induction and microbial community dynamics

Treatment of acid mine drainage by forward osmosis: Heavy metal rejection and reverse flux of draw solution constituents

Microaeration for hydrogen sulfide removal in UASB reactor

Removal of H2S by a continuous microalgae-based photosynthetic biogas upgrading process

Potentials and limits of anaerobic digestion of sewage sludge: Energy self-sufficient municipal wastewater treatment plant?

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