Garden and food waste co-fermentation for biohydrogen and biomethane production in a two-step hyperthermophilic-mesophilic process

Abreu, A. A.; Tavares, Fernando; Alves, M. M.; Cavaleiro, A. J.; Pereira, M. A.

doi:10.1016/j.biortech.2019.01.085

Cited by 75 publications

(20 citation statements)

References 42 publications

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“…Particularly, bioenergy research is increasingly looking for non-edible sources of biomass and for bio-based environmentally friendly processes. The biomass resources from agriculture [3][4][5], forest [6][7][8] and municipal waste [9][10][11] can be converted biologically or thermochemically. However, the biological conversion can be hindered by the presence of low-biodegradable organic matter.…”

Section: Context Challenges and Aimmentioning

confidence: 99%

Bioelectrochemical systems (BESs) towards conversion of carbon monoxide/syngas: A mini-review

Barbosa

Peixoto

Alves

et al. 2021

Renewable and Sustainable Energy Reviews

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Microbial conversion of carbon monoxide (CO)/syngas has been extensively investigated. The microbial conversion of CO/syngas offers numerous advantages over chemically catalyzed processes e.g. the specificity of the biocatalysts, the operation at ambient conditions and high conversion efficiencies. Bioelectrochemical systems (BESs) exploit the capacity of electrochemically active bacteria (EAB) to use insoluble electron acceptors or donors to produce electricity or added-value compounds. Electricity production from different organic sources in BESs has been broadly demonstrated, whereas electricity production from CO/syngas has been very little reported. Acetate oxidation by a consortium of carboxydotrophic and CO-tolerant EAB has been suggested to be the main pathway responsible for indirect electricity generation from CO/syngas. Although electricity production in BESs from several organic sources has been widely investigated, the interest on BESs research is currently moving to the production of added-value compounds by electro-fermentation (EF) processes. EF allows to modify redox balances by the use of electric circuits to fine tune metabolic pathways towards obtaining products with high economic value. Although EF has been widely studied, the potential of use CO-rich gas streams as substrate has been under explored. This review presents and discusses current advances on microbial conversion of CO/syngas in BESs.

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Section: Context Challenges and Aimmentioning

confidence: 99%

Bioelectrochemical systems (BESs) towards conversion of carbon monoxide/syngas: A mini-review

Barbosa

Peixoto

Alves

et al. 2021

Renewable and Sustainable Energy Reviews

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“…According to these studies, the highest biogas production could be achieved when the hyperthermophilic pretreatment was combined with thermophilic digestion in a subsequent stage. In contrast, Abbreu et al [16] successfully applied a two-step hyperthermophilic-mesophilic digestion process for the treatment of garden and food waste. The authors reported that hydrogen was produced in the hyperthermophilic stage, whereas methane was generated in the mesophilic step.…”

Section: Introductionmentioning

confidence: 99%

Co-Digestion of Kitchen Waste with Grass and Leaves after Hyperthermophilic Pretreatment for Methane and Hydrogen Production

Liczbiński

Borowski

2021

Energies

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The study investigated co-digestion batch experiments using kitchen waste (KW) and garden waste (GW) collected from individual households. Grass and leaves were first subjected to a 3-day hyperthermophilic pretreatment at 70 °C and 80 °C and then co-digested with kitchen waste at 35 °C and 55 °C. The hyperthermophilic pretreatment resulted in the solubilization of organic material with the release of fatty acids, whereas the biogas yield was negligible. In the second stage, the greatest methane yield of 387 NmL/gVS was achieved for the mono-digestion of leaves, whereas the co-digestion of grass with 50% KW gave the highest hydrogen production of 88 NmL/gVS. Considering the overall process performance, the best operating conditions were established using a 3-day hyperthermophilic pretreatment at 70 °C, followed by co-digestion at 55 °C in the second stage for the mixture of 25% garden waste with 75% KW.

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“…Garden and park waste are generated from the maintenance of private gardens and public parks, and represent an economic substrate to produce biohythane (a mixture of hydrogen and methane, usually with 10 to 25% hydrogen in volume) and hydrogen via anaerobic dark fermentation [77,134,135]. In general, we can identify three major components: an organic fraction from garden grass, small bushes containing an undefined organic content and inorganic elements (on a dry matter basis, 0.6% N, 0.1% P, and 1.0% K), and ash, whose content is related to the amount of soil present.…”

Section: Garden Wastementioning

confidence: 99%

Fermentation of Biodegradable Organic Waste by the Family Thermotogaceae

et al. 2021

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The abundance of organic waste generated from agro-industrial processes throughout the world has become an environmental concern that requires immediate action in order to make the global economy sustainable and circular. Great attention has been paid to convert such nutrient-rich organic waste into useful materials for sustainable agricultural practices. Instead of being an environmental hazard, biodegradable organic waste represents a promising resource for the production of high value-added products such as bioenergy, biofertilizers, and biopolymers. The ability of some hyperthermophilic bacteria, e.g., the genera Thermotoga and Pseudothermotoga, to anaerobically ferment waste with the concomitant formation of bioproducts has generated great interest in the waste management sector. These biotechnologically significant bacteria possess a complementary set of thermostable enzymes to degrade complex sugars, with high production rates of biohydrogen gas and organic molecules such as acetate and lactate. Their high growth temperatures allow not only lower contamination risks but also improve substrate solubilization. This review highlights the promises and challenges related to using Thermotoga and Pseudothermotoga spp. as sustainable systems to convert a wide range of biodegradable organic waste into high value-added products.

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Garden and food waste co-fermentation for biohydrogen and biomethane production in a two-step hyperthermophilic-mesophilic process

Cited by 75 publications

References 42 publications

Bioelectrochemical systems (BESs) towards conversion of carbon monoxide/syngas: A mini-review

Bioelectrochemical systems (BESs) towards conversion of carbon monoxide/syngas: A mini-review

Co-Digestion of Kitchen Waste with Grass and Leaves after Hyperthermophilic Pretreatment for Methane and Hydrogen Production

Fermentation of Biodegradable Organic Waste by the Family Thermotogaceae

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