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Quantification and Modelling of Fugitive Greenhouse Gas Emissions from Urban Water Systems: A report from the IWA Task Group on GHG [Pehme köide]

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  • Formaat: Paperback / softback, 280 pages, kõrgus x laius x paksus: 234x156x18 mm
  • Sari: Scientific and Technical Report Series
  • Ilmumisaeg: 15-Apr-2022
  • Kirjastus: IWA Publishing
  • ISBN-10: 1789060451
  • ISBN-13: 9781789060454
Teised raamatud teemal:
Quantification and Modelling of Fugitive Greenhouse Gas Emissions from Urban Water Systems: A report from the IWA Task Group on GHGSuurem pilt
  • Formaat: Paperback / softback, 280 pages, kõrgus x laius x paksus: 234x156x18 mm
  • Sari: Scientific and Technical Report Series
  • Ilmumisaeg: 15-Apr-2022
  • Kirjastus: IWA Publishing
  • ISBN-10: 1789060451
  • ISBN-13: 9781789060454
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781789060454.html
Märksõnad:
With increased commitment from the international community to reduce greenhouse gas (GHG) emissions from all sectors in accordance with the Paris Agreement, the water sector has never felt the pressure it is now under to transition to a low-carbon water management model. This requires reducing GHG emissions from grid-energy consumption (Scope 2 emissions), which is straightforward; however, it also requires reducing Scope 1 emissions, which include nitrous oxide and methane emissions, predominantly from wastewater handling and treatment.

The pathways and factors leading to biological nitrous oxide and methane formation and emissions from wastewater are highly complex and site-specific. Good emission factors for estimating the Scope 1 emissions are lacking, water utilities have little experience in directly measuring these emissions, and the mathematical modelling of these emissions is challenging. Therefore, this book aims to help the water sector address the Scope 1 emissions by breaking down their pathways and influencing factors, and providing guidance on both the use of emission factors, and performing direct measurements of nitrous oxide and methane emissions from sewers and wastewater treatment plants. The book also dives into the mathematical modelling for predicting these emissions and provides guidance on the use of different mathematical models based upon your conditions, as well as an introduction to alternative modelling methods, including metabolic, data-driven, and AI methods. Finally, the book includes guidance on using the modelling tools for assessing different operating strategies and identifying promising mitigation actions.

A must have book for anyone needing to understand, account for, and reduce water utility Scope 1 emissions.
List of Contributors
xi
Foreword xiii
Acknowledgements xv
Chapter 1 Introduction
1(10)
Liu Ye
Jose Porro
Summary
1(1)
Terminology
1(1)
1.1 Climate Change, Sustainability, and GHG Legislation in the Water Sector
2(1)
1.2 Overview of GHG Emission Sources in Urban Water Systems
3(2)
1.3 GHG Emissions Inventory Protocols
5(1)
1.4 Direct Measurement of Urban Water System GHG Emissions
6(1)
1.5 Modelling Tools for Assessing GHG Emissions from Urban Water Systems
6(1)
1.6 Mitigation of GHG Emissions from Urban Water Systems
7(1)
1.7 General Guide for Use of this Book in GHG Assessment and Reduction Efforts
8(1)
Acknowledgement
8(1)
References
8(1)
Nomenclature
9(2)
Chapter 2 Full-scale source, mechanisms and factors affecting nitrous oxide emissions
11(32)
Maite Pijuan
Yingfen Zhao
Summary
11(1)
Terminology
11(2)
2.1 Introduction
13(3)
2.2 Pathways Leading to N20 Production
16(3)
2.2.1 N20 production during nitrification
16(2)
2.2.2 N20 production during denitrification
18(1)
2.2.3 N20 production through abiotic pathways
19(1)
2.3 Factors Affecting N20 Production
19(13)
2.3.1 Factors influencing N20 production during nitrification
19(6)
2.3.2 Factors influencing N20 production during denitrification
25(5)
2.3.3 Effect of environmental conditions on N20 production during nitrification and denitrification
30(2)
2.4 Concluding Remarks
32(1)
Acknowledgements
32(1)
References
32(8)
Nomenclature
40(3)
Chapter 3 Mechanisms, source, and factors that affect methane emissions
43(20)
Oriol Gutierrez
Haoran Duan
Ziping Wu
Keshab R. Sharma
Summary
43(1)
Terminology
44(1)
3.1 Introduction and Context
44(1)
3.2 Biological Processes Involved in Methane Generation
45(2)
3.3 Methane Emissions in Urban Wastewater Systems
47(1)
3.4 Methane Emissions from Sewer Systems: Factors and Sources
48(5)
3.4.1 Methane production in anaerobic sewer biofilms
50(1)
3.4.2 Methane production in sewer sediments
50(1)
3.4.3 Factors affecting methane production and emission in sewers
51(2)
3.5 Methane Emissions from WWTPs Including Anaerobic Processes for Wastewater and Sludge Treatment
53(5)
3.5.1 Anaerobic wastewater treatments as sources of methane emissions
53(2)
3.5.2 Methane emissions from sludge handling processes
55(3)
3.6 Concluding Remarks
58(1)
Acknowledgements
58(1)
References
58(3)
Nomenclature
61(2)
Chapter 4 Reporting guidelines
63(28)
Ariane Coelho Emtio
Amanda Lake
Summary
63(1)
Terminology
63(1)
4.1 Introduction
64(1)
4.2 Accounting Considerations
65(6)
4.2.1 Reporting scope considerations for the water industry
65(4)
4.2.2 Top-down and bottom-up approach considerations for the water sector
69(2)
4.3 International Methodologies
71(10)
4.3.1 The intergovernmental panel on climate change
71(1)
4.3.2 IPCC methodologies for the water sector
72(9)
4.4 National Guidelines
81(5)
4.4.1 Methane
81(1)
4.4.2 Nitrous oxide
82(4)
References
86(3)
Nomenclature
89(2)
Chapter 5 Full-scale quantification of N2Q and CH4 emissions from urban water systems
91(42)
Vanessa Parravicini
Ahlem Filali
Antonio Delre
Oriol Gutierrez
Haoran Duan
Summary
91(1)
Terminology
92(1)
5.1 Introduction
92(1)
5.2 Quantification of GHG Emissions in Sewers
93(5)
5.2.1 Quantification methods of CH4 emissions in sewers
94(1)
5.2.2 Measurement of CH4 in the liquid phase
95(1)
5.2.3 Measurement of CH4 in the gas phase
96(2)
5.2.4 Recommended measurement practice
98(1)
5.3 Quantification of GHG Emissions in Wastewater Treatment Plants
98(26)
5.3.1 Plant-wide quantification of N20 and CH4 emissions
99(3)
5.3.2 Process-unit quantification of N20 and CH4 emissions
102(17)
5.3.3 Recommendations for selecting the measurement method
119(2)
5.3.4 Recommended data requirements
121(3)
5.4 Conclusions and Perspectives
124(1)
Acknowledgements
124(1)
References
124(6)
Nomenclature
130(3)
Chapter 6 Full-scale emission results (N2Q and CH4)
133(634)
Vasileia Vasilaki
Made Pijuan
Haoran Duan
Evina Katsou
Summary
133(1)
Terminology
134(1)
6.1 Introduction
135(1)
6.2 N20 Emissions from Full-Scale WWTP Monitoring Results
136(15)
6.2.1 Processes treating low strength streams
146(3)
6.2.2 Processes treating high strength (high nitrogen loading) streams
149(2)
6.3 CH4 Emissions from Full-Scale WWTPs
151(4)
6.3.1 WWTPs without anaerobic sludge handling
151(1)
6.3.2 WWTPs with anaerobic sludge handling
151(3)
6.3.3 WWTPs with anaerobic wastewater treatment technologies
154(1)
6.4 GHG Emissions from Sewer Networks
155(1)
6.4.1 Reported CH4 emissions from sewer networks
155(1)
6.4.2 Reported N2O emissions from sewer networks
155(1)
6.5 Mitigation Strategies Applied in Full-Scale Systems
155(3)
6.5.1 GHG mitigation in WWTPs
155(2)
6.5.2 GHG mitigation from sewers
157(1)
6.6 Concluding Remarks
158(1)
Acknowledgements
159(1)
References
159(6)
Nomenclature
165(2)
Chapter 7 Modelling N2G production and emissions
167(1)
Mathieu Sperandio
Longqi Lang
Fabrizio Sabba
Robert Nerenberg
Peter Vanrolleghem
Carlos Domingo-Felez
Earth F. Smets
Haoran Duan
Bing-Jie Ni
Zhiguo Yuan
Summary
167(1)
Terminology
167(1)
7.1 Introduction
168(1)
7.2 N20 Kinetic Model Structures
169(7)
7.2.1 Modelling of N2O production and consumption by Heterotrophic Denitrifiers
169(4)
7.2.2 Modelling N2O production by AOB
173(3)
7.3 Model Integration, Use and Calibration
176(14)
7.3.1 Integrated N2O models
176(1)
7.3.2 Model Evaluation against experimental data
177(3)
7.3.3 Selection of models for N2O Prediction
180(3)
7.3.4 Key kinetic and stoichiometric parameters for calibration
183(2)
7.3.5 Application of N2O models in biofilm systems
185(2)
7.3.6 Application of N2O models in full-scale WWTPs
187(3)
7.4 Conclusions and Perspectives
190(1)
Acknowledgements
191(1)
References
191(4)
Nomenclature
195(2)
Chapter 8 Modelling of methane production and emissions
197(16)
Keshab Sharma
Oriol Gutierrez
Zhiguo Yuan
Matthijs R. J. Daelman
Mark C. M. van Loosdrecht
Eveline I. P. Volcke
Summary
197(1)
Terminology
197(1)
8.1 Introduction
198(1)
8.2 CH4 Modelling for Collection System
198(8)
8.2.1 Mechanistic model for CH4 production in sewer biofilms
198(1)
8.2.2 Methane oxidation under aerobic environment
199(2)
8.2.3 Methane production in sewer sediments
201(2)
8.2.4 Empirical models predicting methane production in sewers
203(1)
8.2.5 Methane emission in sewers
204(1)
8.2.6 Model calibration and validation
205(1)
8.2.7 Further model development
205(1)
8.3 Methane Modelling for Activated Sludge Process
206(3)
8.3.1 Incorporating aerobic methane oxidation in activated sludge models
206(1)
8.3.2 Modelling methane gas-liquid mass transfer
206(3)
8.4 Methane Modelling for Anaerobic Digestion
209(1)
References
209(2)
Nomenclature
211(2)
Chapter 9 Benchmarking strategies to control GHG production and emissions
213(16)
Xavier Flores-Alsina
Magnus Arnell
Lluis Corominas
Chris Sweetapple
Guanglao Fu
David Butler
Peter A. Vanrolleghem
Krist V. Gernaey
Ulf Jeppsson
Summary
213(1)
Terminology
214(1)
9.1 Introduction
214(1)
9.2 Benchmark Plant Description
214(1)
9.3 Benchmark Model Upgrades and Modifications
215(1)
9.3.1 Activated sludge model (ASM)
215(1)
9.3.2 ASM/ADM interface
216(1)
9.3.3 Mass transfer
216(1)
9.3.4 Temperature correction
216(1)
9.3.5 Other ancillary models
216(1)
9.4 Evaluation Criteria
216(2)
9.4.1 Effluent quality (EQI) and operational cost (OCI) indices
216(1)
9.4.2 On-site/off-site GHG emissions
217(1)
9.4.3 Sustainability indicators
218(1)
9.5 Examples/Case Studies
218(5)
9.5.1 Case study #1: evaluation of plant-wide control strategies
218(2)
9.5.2 Case study #2: investigating the impact of net energy reduction on sustainability
220(3)
9.5.3 Other relevant case studies
223(1)
9.6 Limitations
223(1)
9.7 Conclusions and Perspectives
223(1)
References
224(3)
Nomenclature
227(2)
Chapter 10 Knowledge-based and data-driven approaches for assessing greenhouse gas emissions from wastewater systems
229(16)
Jose Porro
Vasileia Vasilaki
Giacomo Bellandi
Evina Katsou
Summary
229(1)
Terminology
229(1)
10.1 Introduction
230(1)
10.2 Knowledge-Based Artificial Intelligence
230(5)
10.2.1 Integrating knowledge-based AI with mechanistic process models
232(1)
10.2.2 Hybrid biokinetic/CFD and knowledge-based AI model
232(3)
10.3 Data-Driven Approaches
235(3)
10.4 Conclusions and Perspectives
238(4)
Acknowledgements
242(1)
References
242(2)
Nomenclature
244(1)
Chapter 11 Perspectives on fugitive GHGs reduction from urban wastewater systems
245(14)
Ingmar Nopens
Jose Porro
Liu Ye
Summary
245(1)
Terminology
245(1)
11.1 A Summary on the State-of-the-Art Knowledge in Quantification and Modelling of Fugitive GHG Emissions from Urban Wastewater Systems
246(1)
11.2 Issues, Knowledge Gaps and Perspectives on GHG Quantification Methods and the Reporting Guidelines
246(3)
11.2.1 GHG quantification
246(2)
11.2.2 Reporting guidelines
248(1)
11.3 Issues, Knowledge Gaps and Perspectives on GHG Modelling
249(2)
11.4 GHG Mitigation Strategy and Perspectives
251(4)
11.4.1 N20 mitigation
251(3)
11.4.2 CH4 mitigation
254(1)
11.5 Overall Conclusion
255(1)
Acknowledgement
255(1)
References
255(2)
Nomenclature
257(2)
A note from the 1WA Task Group GHG 259