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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.

Technology: general issues --- Environmental science, engineering & technology --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability

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• Reference Manager
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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.

Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability

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This Special Issue, consisting of 14 papers, presents the latest findings concerning both numerical and experimental investigations. Their aim is to achieve a reduction in pollutant emissions, as well as an improvement in fuel economy and performance, for internal combustion engines. This will provide readers with a comprehensive, unbiased, and scientifically sound overview of the most recent research and technological developments in this field. More specific topics include: 3D CFD detailed analysis of the fuel injection, combustion and exhaust aftertreatments processes, 1D and 0D, semi-empirical, neural network-based control-oriented models, experimental analysis and the optimization of both conventional and innovative combustion processes.

History of engineering & technology --- homogeneous charge compression ignition (HCCI) --- exhaust gas recirculation (EGR) --- dual-fuel --- dimethyl ether (DME) --- exhaust emission --- co-combustion --- dual fuel --- combustion stability --- coefficient of variation of IMEP --- probability density of IMEP --- 0D model --- predictive model --- tumble --- turbulent intensity --- spark-ignition engine --- engine geometry --- AdBlue® injection --- large eddy simulation --- Eulerian–Lagrangian approach --- thermal decomposition --- wall–film formation --- conversion efficiency --- hybrid electric vehicle --- real driving emissions --- fuel consumption --- vehicle performance --- electric supercharger --- Lambda-1 engine --- 48 V Mild Hybrid --- electrically assisted turbocharger --- variable geometry turbocharger-exhaust gas recirculation --- oxygen concentration --- active disturbance rejection control --- model-based --- control --- diesel engine --- ANN --- physics-based model --- semi-empirical model --- CNG --- diesel fuel --- dual fuel engine --- rate of heat release --- ignition delay --- burn duration --- exhaust gas emission --- camless --- electromagnetic variable valve train --- magnetorheological buffer --- soft landing --- solenoid injectors --- indirect-acting piezoelectric injectors --- direct-acting piezoelectric injectors --- engine-out emissions --- combustion noise --- diesel engines --- pollutant emission reduction --- mixing process --- advanced injection strategy --- varying injection rate --- engine torque estimation --- GDI engines --- extended state observer --- online performance --- torque --- nitrogen oxide emissions --- model-based control --- engines --- numerical simulation --- pollutant emissions prediction --- computational fluid dynamics

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Although air pollution is usually linked with human activities, natural processes may also lead to major concentrations of hazardous substances in the low atmosphere. Pollutant levels may be reduced when emissions can be controlled. However, the impact of meteorological variables on the concentrations measured may be noticeable, and these variables cannot be controlled. This book is devoted to the influence of meteorological processes on the pollutant concentrations recorded in the low atmosphere. Measurements, cycles, statistical procedures, as well as specific variables such as the synoptic pattern, temperature inversion, or the calculation of back-trajectories, are considered in the studies included in this book to highlight the relationship between air pollution and meteorological variables. In addition, the state of the art of this subject following meteorological scales, from micro to macro-scale, is presented. Consequently, this book focuses on applied science and seeks to further current knowledge of what contribution meteorological processes make to the concentrations measured in order to achieve greater control over air pollution.

Research & information: general --- air pollution --- synoptic situation pattern --- meteorological variables --- threshold values --- air quality forecast --- modelling --- pollution episodes --- national holiday --- COVID-19 --- particulate matter --- natural ventilation --- indoor air quality --- regional variation --- nitrogen dioxide --- in situ urban concentrations --- meteorological measurements --- NO2 variation --- partial correlation --- gross alpha activity --- northern Iberian Peninsula --- radon --- airflow patterns --- surface winds --- atmospheric boundary layer --- weather types --- Gaussian plume model --- low-level jet --- recirculation --- microscale --- macroscale --- mesoscale --- source apportionment --- cluster analysis --- health risks --- residential wood burning --- sustainable urban development --- urban haze --- temperature inversion --- Obukhov length --- HYSPLIT --- biomass burning --- cold surge, emission --- BaP --- HPLC --- carcinogenic --- diagnostic ratio --- air pollution --- synoptic situation pattern --- meteorological variables --- threshold values --- air quality forecast --- modelling --- pollution episodes --- national holiday --- COVID-19 --- particulate matter --- natural ventilation --- indoor air quality --- regional variation --- nitrogen dioxide --- in situ urban concentrations --- meteorological measurements --- NO2 variation --- partial correlation --- gross alpha activity --- northern Iberian Peninsula --- radon --- airflow patterns --- surface winds --- atmospheric boundary layer --- weather types --- Gaussian plume model --- low-level jet --- recirculation --- microscale --- macroscale --- mesoscale --- source apportionment --- cluster analysis --- health risks --- residential wood burning --- sustainable urban development --- urban haze --- temperature inversion --- Obukhov length --- HYSPLIT --- biomass burning --- cold surge, emission --- BaP --- HPLC --- carcinogenic --- diagnostic ratio

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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.

Technology: general issues --- Environmental science, engineering & technology --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability