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Methane fermentation --- Optimization methods --- Infrared spectrophotometry --- Alkalinity --- Volatile fatty acids --- Atomic absorption spectrometry --- Bioreactors --- Biogas
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Beta vulgaris --- leaves --- biomass --- bioconversion. --- bioconversion --- Enzyme activity --- Volatile fatty acids
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Biofuels --- Fermentation --- Volatile fatty acids --- bioconversion. --- bioconversion --- Hydrogenation. --- Hydrogenation --- Waste utilization
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Ruminants contribute significantly to human food security. However, the production of ruminants contributes to greenhouse gas (GHG) emissions that are responsible for climate change. GHGs such as methane, carbon dioxide, and nitrous oxide are produced from different processes of ruminant production. Ruminant enteric methane is a substantial component of methane produced by agriculture. This book presents novel and established methods in quantifying and reducing enteric methane emission from ruminants in different production systems. The book covers different types of ruminants including cattle, sheep, and goats. The chapters are contributed by scientists and authors from different parts of the world, demonstrating the importance of this problem and the universal drive for immediate and sustainable solutions. Although, biologically speaking, the production of enteric methane cannot be reduced to zero, high emissions are an indicator of inefficient digestion of feed in the rumen and low utilisation of feed energy. By presenting research that could lead to robust and yet practical quantification methods and mitigation strategies, this book not only contributes to the discourse and new knowledge on the magnitude of the problem but also brings forward potential solutions in different livestock production systems.
Research & information: general --- Biology, life sciences --- Technology, engineering, agriculture --- environmental modelling --- pasture systems --- nitrous oxide --- methane emissions --- nitrate leaching --- climate change --- heat stress --- goat --- immunization --- methane --- volatile fatty acids --- backgrounded cattle --- encapsulated nitrate --- essential oil --- nitrogen balance --- reduction strategy --- rumen fermentation --- microbial flora --- tea saponins --- Moringa oleifera --- fecal methanogenic community --- dairy cows --- mcrA gene sequencing technique --- methane emission --- tropical beef cattle --- Desmanthus --- supplementation --- growth performance --- ruminant nutrition --- legumes --- NDIR --- laser --- agreement --- enteric emissions --- interchangeability --- heifer --- forage-to-concentrate ratio --- prediction equation --- sulphur hexafluoride tracer technique --- genetic evaluation --- greenhouse gases --- environment --- dairy goat farming --- linear programming --- GHG emissions --- abatement cost --- mitigation options --- carbon footprint
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Ruminants contribute significantly to human food security. However, the production of ruminants contributes to greenhouse gas (GHG) emissions that are responsible for climate change. GHGs such as methane, carbon dioxide, and nitrous oxide are produced from different processes of ruminant production. Ruminant enteric methane is a substantial component of methane produced by agriculture. This book presents novel and established methods in quantifying and reducing enteric methane emission from ruminants in different production systems. The book covers different types of ruminants including cattle, sheep, and goats. The chapters are contributed by scientists and authors from different parts of the world, demonstrating the importance of this problem and the universal drive for immediate and sustainable solutions. Although, biologically speaking, the production of enteric methane cannot be reduced to zero, high emissions are an indicator of inefficient digestion of feed in the rumen and low utilisation of feed energy. By presenting research that could lead to robust and yet practical quantification methods and mitigation strategies, this book not only contributes to the discourse and new knowledge on the magnitude of the problem but also brings forward potential solutions in different livestock production systems.
Research & information: general --- Biology, life sciences --- Technology, engineering, agriculture --- environmental modelling --- pasture systems --- nitrous oxide --- methane emissions --- nitrate leaching --- climate change --- heat stress --- goat --- immunization --- methane --- volatile fatty acids --- backgrounded cattle --- encapsulated nitrate --- essential oil --- nitrogen balance --- reduction strategy --- rumen fermentation --- microbial flora --- tea saponins --- Moringa oleifera --- fecal methanogenic community --- dairy cows --- mcrA gene sequencing technique --- methane emission --- tropical beef cattle --- Desmanthus --- supplementation --- growth performance --- ruminant nutrition --- legumes --- NDIR --- laser --- agreement --- enteric emissions --- interchangeability --- heifer --- forage-to-concentrate ratio --- prediction equation --- sulphur hexafluoride tracer technique --- genetic evaluation --- greenhouse gases --- environment --- dairy goat farming --- linear programming --- GHG emissions --- abatement cost --- mitigation options --- carbon footprint
Choose an application
Ruminants contribute significantly to human food security. However, the production of ruminants contributes to greenhouse gas (GHG) emissions that are responsible for climate change. GHGs such as methane, carbon dioxide, and nitrous oxide are produced from different processes of ruminant production. Ruminant enteric methane is a substantial component of methane produced by agriculture. This book presents novel and established methods in quantifying and reducing enteric methane emission from ruminants in different production systems. The book covers different types of ruminants including cattle, sheep, and goats. The chapters are contributed by scientists and authors from different parts of the world, demonstrating the importance of this problem and the universal drive for immediate and sustainable solutions. Although, biologically speaking, the production of enteric methane cannot be reduced to zero, high emissions are an indicator of inefficient digestion of feed in the rumen and low utilisation of feed energy. By presenting research that could lead to robust and yet practical quantification methods and mitigation strategies, this book not only contributes to the discourse and new knowledge on the magnitude of the problem but also brings forward potential solutions in different livestock production systems.
environmental modelling --- pasture systems --- nitrous oxide --- methane emissions --- nitrate leaching --- climate change --- heat stress --- goat --- immunization --- methane --- volatile fatty acids --- backgrounded cattle --- encapsulated nitrate --- essential oil --- nitrogen balance --- reduction strategy --- rumen fermentation --- microbial flora --- tea saponins --- Moringa oleifera --- fecal methanogenic community --- dairy cows --- mcrA gene sequencing technique --- methane emission --- tropical beef cattle --- Desmanthus --- supplementation --- growth performance --- ruminant nutrition --- legumes --- NDIR --- laser --- agreement --- enteric emissions --- interchangeability --- heifer --- forage-to-concentrate ratio --- prediction equation --- sulphur hexafluoride tracer technique --- genetic evaluation --- greenhouse gases --- environment --- dairy goat farming --- linear programming --- GHG emissions --- abatement cost --- mitigation options --- carbon footprint
Choose an application
Anaerobic digestion (AD) is one of the oldest biotechnological processes and originally referred to biomass degradation under anoxic conditions in both natural and engineered systems. It has been used for decades to treat various waste streams and to produce methane-rich biogas as an important energy carrier, and it has become a major player in electrical power production. AD is a popular, mature technology, and our knowledge about the influencing process parameters as well as about the diverse microbial communities involved in the process has increased dramatically over the last few decades. To avoid competition with food and feed production, the AD feedstock spectrum has constantly been extended to waste products either rich in recalcitrant lignocellulose or containing inhibitory substances such as ammonia, which requires application of various pre-treatments or specific management of the microbial resources. Extending the definition of AD, it can also convert gases rich in hydrogen and carbon dioxide into methane that can substitute natural gas, which opens new opportunities by a direct link to traditional petrochemistry. Furthermore, AD can be coupled with emerging biotechnological applications, such as microbial electrochemical technologies or the production of medium-chain fatty acids by anaerobic fermentation. Ultimately, because of the wide range of applications, AD is still a very vital field in science. This Special Issue highlights some key topics of this research field.
Research & information: general --- Biology, life sciences --- anaerobic digestion --- solid digestate --- milling process --- sugars recovery --- energy balances --- bioethanol production --- biogas upgrading --- biomethane --- bio-succinic acid --- CO2 utilization --- feasibility assessment --- acetate --- lactate --- inoculum --- food waste --- sewage sludge --- lactic acid bacteria --- cattle manure --- steam explosion --- pre-treatment --- UASB --- co-digestion --- biogas --- high-rate anaerobic digestion --- energy recovery --- granular sludge --- renewable energy --- decentralized wastewater treatment --- two-stage anaerobic digestion --- Anammox --- enzyme application --- rheology of digestate --- methane --- aquaculture --- trout --- sludge --- wastewater --- drum sieve --- microfiltration --- settling --- waste-to-energy --- wet waste --- bioenergy --- techno-economic analysis --- ammonia inhibition --- chicken manure --- dairy cow manure --- high-solids anaerobic digestion --- inoculum adaptation --- volatile fatty acids --- dry batch anaerobic digestion --- percolation --- permeability --- Salmonella spp. --- Escherichia coli O157 --- Listeria monocytogenes --- Enterococcus faecalis --- Clostridium spp. --- digestate --- pathogens --- sustainable farming --- anaerobic digester --- antibiotics removal --- antimicrobial --- chlortetracycline --- Tylosin --- n/a
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The transition towards renewable energy sources and “green” technologies for energy generation and storage is expected to mitigate the climate emergency in the coming years. However, in many cases, this progress has been hampered by our dependency on critical materials or other resources that are often processed at high environmental burdens. Yet, many studies have shown that environmental and energy issues are strictly interconnected and require a comprehensive understanding of resource management strategies and their implications. Life cycle assessment (LCA) is among the most inclusive analytical techniques to analyze sustainability benefits and trade-offs within complex systems and, in this Special Issue, it is applied to assess the mutual influences of environmental and energy dimensions. The selection of original articles, reviews, and case studies addressed covers some of the main driving applications for energy requirements and greenhouse gas emissions, including power generation, bioenergy, biorefinery, building, and transportation. An insightful perspective on the current topics and technologies, and emerging research needs, is provided. Alone or in combination with integrative methodologies, LCA can be of pivotal importance and constitute the scientific foundation on which a full system understanding can be reached.
Research & information: general --- life cycle assessment --- harmonization --- photovoltaic --- perovskite solar cell --- manufacturing process --- environmental impact --- greenhouse gas --- gasification --- swine manure management --- ground-source heat pumps --- space conditioning --- environmental sustainability --- life cycle assessment (LCA) --- phase-change material (PCM) --- CED --- Eco-indicator 99 --- IPCC --- LCA --- photovoltaics panels --- recycling --- landfill --- embodied energy --- embodied carbon --- life-cycle embodied performance --- metropolitan area --- in-city --- transport energy intensity --- well to wheel --- material structure --- photovoltaics --- waste management --- EROI --- net energy --- energy scenario --- energy transition --- electricity --- grid mix --- storage --- decarbonization --- biofuel policy --- GHG mitigation --- energy security --- indirect land use change --- carbon dioxide capture --- activated carbon --- environmental impacts --- Life Cycle Assessment (LCA) --- Material Flow Analysis (MFA) --- Criticality --- traction batteries --- forecast --- supply --- exergy --- sustainability --- review --- bioenergy --- geographic information system (GIS) --- harvesting residues --- energy metrics --- PHAs --- bio-based polymers --- biodegradable plastics --- pyrolysis --- volatile fatty acids --- phase change materials --- PCM --- thermal energy storage --- Storage LCA Tool --- Speicher LCA --- n/a
Choose an application
Anaerobic digestion (AD) is one of the oldest biotechnological processes and originally referred to biomass degradation under anoxic conditions in both natural and engineered systems. It has been used for decades to treat various waste streams and to produce methane-rich biogas as an important energy carrier, and it has become a major player in electrical power production. AD is a popular, mature technology, and our knowledge about the influencing process parameters as well as about the diverse microbial communities involved in the process has increased dramatically over the last few decades. To avoid competition with food and feed production, the AD feedstock spectrum has constantly been extended to waste products either rich in recalcitrant lignocellulose or containing inhibitory substances such as ammonia, which requires application of various pre-treatments or specific management of the microbial resources. Extending the definition of AD, it can also convert gases rich in hydrogen and carbon dioxide into methane that can substitute natural gas, which opens new opportunities by a direct link to traditional petrochemistry. Furthermore, AD can be coupled with emerging biotechnological applications, such as microbial electrochemical technologies or the production of medium-chain fatty acids by anaerobic fermentation. Ultimately, because of the wide range of applications, AD is still a very vital field in science. This Special Issue highlights some key topics of this research field.
Research & information: general --- Biology, life sciences --- anaerobic digestion --- solid digestate --- milling process --- sugars recovery --- energy balances --- bioethanol production --- biogas upgrading --- biomethane --- bio-succinic acid --- CO2 utilization --- feasibility assessment --- acetate --- lactate --- inoculum --- food waste --- sewage sludge --- lactic acid bacteria --- cattle manure --- steam explosion --- pre-treatment --- UASB --- co-digestion --- biogas --- high-rate anaerobic digestion --- energy recovery --- granular sludge --- renewable energy --- decentralized wastewater treatment --- two-stage anaerobic digestion --- Anammox --- enzyme application --- rheology of digestate --- methane --- aquaculture --- trout --- sludge --- wastewater --- drum sieve --- microfiltration --- settling --- waste-to-energy --- wet waste --- bioenergy --- techno-economic analysis --- ammonia inhibition --- chicken manure --- dairy cow manure --- high-solids anaerobic digestion --- inoculum adaptation --- volatile fatty acids --- dry batch anaerobic digestion --- percolation --- permeability --- Salmonella spp. --- Escherichia coli O157 --- Listeria monocytogenes --- Enterococcus faecalis --- Clostridium spp. --- digestate --- pathogens --- sustainable farming --- anaerobic digester --- antibiotics removal --- antimicrobial --- chlortetracycline --- Tylosin --- n/a
Choose an application
The transition towards renewable energy sources and “green” technologies for energy generation and storage is expected to mitigate the climate emergency in the coming years. However, in many cases, this progress has been hampered by our dependency on critical materials or other resources that are often processed at high environmental burdens. Yet, many studies have shown that environmental and energy issues are strictly interconnected and require a comprehensive understanding of resource management strategies and their implications. Life cycle assessment (LCA) is among the most inclusive analytical techniques to analyze sustainability benefits and trade-offs within complex systems and, in this Special Issue, it is applied to assess the mutual influences of environmental and energy dimensions. The selection of original articles, reviews, and case studies addressed covers some of the main driving applications for energy requirements and greenhouse gas emissions, including power generation, bioenergy, biorefinery, building, and transportation. An insightful perspective on the current topics and technologies, and emerging research needs, is provided. Alone or in combination with integrative methodologies, LCA can be of pivotal importance and constitute the scientific foundation on which a full system understanding can be reached.
Research & information: general --- life cycle assessment --- harmonization --- photovoltaic --- perovskite solar cell --- manufacturing process --- environmental impact --- greenhouse gas --- gasification --- swine manure management --- ground-source heat pumps --- space conditioning --- environmental sustainability --- life cycle assessment (LCA) --- phase-change material (PCM) --- CED --- Eco-indicator 99 --- IPCC --- LCA --- photovoltaics panels --- recycling --- landfill --- embodied energy --- embodied carbon --- life-cycle embodied performance --- metropolitan area --- in-city --- transport energy intensity --- well to wheel --- material structure --- photovoltaics --- waste management --- EROI --- net energy --- energy scenario --- energy transition --- electricity --- grid mix --- storage --- decarbonization --- biofuel policy --- GHG mitigation --- energy security --- indirect land use change --- carbon dioxide capture --- activated carbon --- environmental impacts --- Life Cycle Assessment (LCA) --- Material Flow Analysis (MFA) --- Criticality --- traction batteries --- forecast --- supply --- exergy --- sustainability --- review --- bioenergy --- geographic information system (GIS) --- harvesting residues --- energy metrics --- PHAs --- bio-based polymers --- biodegradable plastics --- pyrolysis --- volatile fatty acids --- phase change materials --- PCM --- thermal energy storage --- Storage LCA Tool --- Speicher LCA --- n/a
Listing 1 - 10 of 21 | << page >> |
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