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RESEARCH PRODUCT
Greenhouse gases from wastewater treatment — A review of modelling tools
Manel Garrido-baserbaAlida CosenzaDonatella CanianiRiccardo GoriDiego RossoGustaf OlssonGiorgio ManninaGiovanni EspositoG. A. Ekamasubject
Greenhouse EffectEnvironmental Engineering0208 environmental biotechnologyAir pollutionBiomassChemicalCarbon footprint; Denitrification; Emission; Greenhouse gas; Methane; Nitrification; Nitrous oxide; Wastewater; Environmental Chemistry; Pollution; Waste Management and Disposal; Environmental Engineering02 engineering and technologyWastewater010501 environmental sciencesmedicine.disease_causeWaste Disposal FluidGreenhouse gas01 natural sciencesGreenhouse gaEmissionModelsAir PollutionEnvironmental monitoringmedicineCarbon footprint; Denitrification; Emission; Greenhouse gas; Methane; Nitrification; Nitrous oxide; Wastewater; Air Pollutants; Air Pollution; Carbon Dioxide; Environmental Monitoring; Greenhouse Effect; Methane; Nitrous Oxide; Waste Disposal Fluid; Waste Water; Models ChemicalEnvironmental ChemistryWaste WaterGreenhouse effectWaste Management and Disposal0105 earth and related environmental sciencesAir PollutantsNitrous oxideSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleScale (chemistry)Waste DisposalEnvironmental engineeringCarbon DioxideEnvironmental economicsCarbon footprintNitrificationPollution020801 environmental engineeringModels ChemicalAir PollutantGreenhouse gasDenitrificationCarbon footprintEnvironmental scienceSewage treatmentFluidMethaneModelEnvironmental Monitoringdescription
Nitrous oxide, carbon dioxide and methane are greenhouse gases (GHG) emitted from wastewater treatment that contribute to its carbon footprint. As a result of the increasing awareness of GHG emissions from wastewater treatment plants (WWTPs), new modelling, design, and operational tools have been developed to address and reduce GHG emissions at the plant-wide scale and beyond. This paper reviews the state-of-the-art and the recently developed tools used to understand and manage GHG emissions from WWTPs, and discusses open problems and research gaps. The literature review reveals that knowledge on the processes related to N2O formation, especially due to autotrophic biomass, is still incomplete. The literature review shows also that a plant-wide modelling approach that includes GHG is the best option for the understanding how to reduce the carbon footprint of WWTPs. Indeed, several studies have confirmed that a wide vision of the WWPTs has to be considered in order to make them more sustainable as possible. Mechanistic dynamic models were demonstrated as the most comprehensive and reliable tools for GHG assessment. Very few plant-wide GHG modelling studies have been applied to real WWTPs due to the huge difficulties related to data availability and the model complexity. For further improvement in GHG plant-wide modelling and to favour its use at large real scale, knowledge of the mechanisms involved in GHG formation and release, and data acquisition must be enhanced.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-01-01 | Science of The Total Environment |