A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions

Sabine Hoffmann; Ulrike Feldmann; Peter M. Bach; Christian Binz; Megan Farrelly; Niki Frantzeskaki; Harald Hiessl; Jennifer Inauen; Tove A. Larsen; Judit Lienert; Jörg Londong; Christoph Lüthi; Max Maurer; Cynthia Mitchell; Eberhard Morgenroth; Kara L. Nelson; Lisa Scholten; Bernhard Truffer; Kai M. Udert

doi:10.1021/acs.est.9b05222

A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions

Sabine Hoffmann^*, Ulrike Feldmann, Peter M. Bach, Christian Binz, Megan Farrelly, Niki Frantzeskaki, Harald Hiessl, Jennifer Inauen, Tove A. Larsen, Judit Lienert, Jörg Londong, Christoph Lüthi, Max Maurer, Cynthia Mitchell, Eberhard Morgenroth, Kara L. Nelson, Lisa Scholten, Bernhard Truffer, Kai M. Udert

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Recent developments in high- and middle-income countries have exhibited a shift from conventional urban water systems to alternative solutions that are more diverse in source separation, decentralization, and modularization. These solutions include nongrid, small-grid, and hybrid systems to address such pressing global challenges as climate change, eutrophication, and rapid urbanization. They close loops, recover valuable resources, and adapt quickly to changing boundary conditions such as population size. Moving to such alternative solutions requires both technical and social innovations to coevolve over time into integrated socio-technical urban water systems. Current implementations of alternative systems in high- and middle-income countries are promising, but they also underline the need for research questions to be addressed from technical, social, and transformative perspectives. Future research should pursue a transdisciplinary research approach to generating evidence through socio-technical “lighthouse” projects that apply alternative urban water systems at scale. Such research should leverage experiences from these projects in diverse socio-economic contexts, identify their potentials and limitations from an integrated perspective, and share their successes and failures across the urban water sector.

Original language	English
Pages (from-to)	5312-5322
Journal	Environmental Science & Technology
Volume	54
Issue number	9
DOIs	https://doi.org/10.1021/acs.est.9b05222
Publication status	Published - 2020

Keywords

Anatomy
Solution chemistry
Wastewater
Chemical structure Water treatment

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1021/acs.est.9b05222

acs.est.9b05222Final published version, 744 KBLicence: Taverne

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Hoffmann, S., Feldmann, U., Bach, P. M., Binz, C., Farrelly, M., Frantzeskaki, N., Hiessl, H., Inauen, J., Larsen, T. A., Lienert, J., Londong, J., Lüthi, C., Maurer, M., Mitchell, C., Morgenroth, E., Nelson, K. L., Scholten, L., Truffer, B., & Udert, K. M. (2020). A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions. Environmental Science & Technology, 54(9), 5312-5322. https://doi.org/10.1021/acs.est.9b05222

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title = "A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions",

abstract = "Recent developments in high- and middle-income countries have exhibited a shift from conventional urban water systems to alternative solutions that are more diverse in source separation, decentralization, and modularization. These solutions include nongrid, small-grid, and hybrid systems to address such pressing global challenges as climate change, eutrophication, and rapid urbanization. They close loops, recover valuable resources, and adapt quickly to changing boundary conditions such as population size. Moving to such alternative solutions requires both technical and social innovations to coevolve over time into integrated socio-technical urban water systems. Current implementations of alternative systems in high- and middle-income countries are promising, but they also underline the need for research questions to be addressed from technical, social, and transformative perspectives. Future research should pursue a transdisciplinary research approach to generating evidence through socio-technical “lighthouse” projects that apply alternative urban water systems at scale. Such research should leverage experiences from these projects in diverse socio-economic contexts, identify their potentials and limitations from an integrated perspective, and share their successes and failures across the urban water sector.",

keywords = "Anatomy, Solution chemistry, Wastewater, Chemical structure Water treatment",

author = "Sabine Hoffmann and Ulrike Feldmann and Bach, {Peter M.} and Christian Binz and Megan Farrelly and Niki Frantzeskaki and Harald Hiessl and Jennifer Inauen and Larsen, {Tove A.} and Judit Lienert and J{\"o}rg Londong and Christoph L{\"u}thi and Max Maurer and Cynthia Mitchell and Eberhard Morgenroth and Nelson, {Kara L.} and Lisa Scholten and Bernhard Truffer and Udert, {Kai M.}",

year = "2020",

doi = "10.1021/acs.est.9b05222",

language = "English",

volume = "54",

pages = "5312--5322",

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Hoffmann, S, Feldmann, U, Bach, PM, Binz, C, Farrelly, M, Frantzeskaki, N, Hiessl, H, Inauen, J, Larsen, TA, Lienert, J, Londong, J, Lüthi, C, Maurer, M, Mitchell, C, Morgenroth, E, Nelson, KL, Scholten, L, Truffer, B & Udert, KM 2020, 'A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions', Environmental Science & Technology, vol. 54, no. 9, pp. 5312-5322. https://doi.org/10.1021/acs.est.9b05222

TY - JOUR

T1 - A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions

AU - Hoffmann, Sabine

AU - Feldmann, Ulrike

AU - Bach, Peter M.

AU - Binz, Christian

AU - Farrelly, Megan

AU - Frantzeskaki, Niki

AU - Hiessl, Harald

AU - Inauen, Jennifer

AU - Larsen, Tove A.

AU - Lienert, Judit

AU - Londong, Jörg

AU - Lüthi, Christoph

AU - Maurer, Max

AU - Mitchell, Cynthia

AU - Morgenroth, Eberhard

AU - Nelson, Kara L.

AU - Scholten, Lisa

AU - Truffer, Bernhard

AU - Udert, Kai M.

PY - 2020

Y1 - 2020

N2 - Recent developments in high- and middle-income countries have exhibited a shift from conventional urban water systems to alternative solutions that are more diverse in source separation, decentralization, and modularization. These solutions include nongrid, small-grid, and hybrid systems to address such pressing global challenges as climate change, eutrophication, and rapid urbanization. They close loops, recover valuable resources, and adapt quickly to changing boundary conditions such as population size. Moving to such alternative solutions requires both technical and social innovations to coevolve over time into integrated socio-technical urban water systems. Current implementations of alternative systems in high- and middle-income countries are promising, but they also underline the need for research questions to be addressed from technical, social, and transformative perspectives. Future research should pursue a transdisciplinary research approach to generating evidence through socio-technical “lighthouse” projects that apply alternative urban water systems at scale. Such research should leverage experiences from these projects in diverse socio-economic contexts, identify their potentials and limitations from an integrated perspective, and share their successes and failures across the urban water sector.

AB - Recent developments in high- and middle-income countries have exhibited a shift from conventional urban water systems to alternative solutions that are more diverse in source separation, decentralization, and modularization. These solutions include nongrid, small-grid, and hybrid systems to address such pressing global challenges as climate change, eutrophication, and rapid urbanization. They close loops, recover valuable resources, and adapt quickly to changing boundary conditions such as population size. Moving to such alternative solutions requires both technical and social innovations to coevolve over time into integrated socio-technical urban water systems. Current implementations of alternative systems in high- and middle-income countries are promising, but they also underline the need for research questions to be addressed from technical, social, and transformative perspectives. Future research should pursue a transdisciplinary research approach to generating evidence through socio-technical “lighthouse” projects that apply alternative urban water systems at scale. Such research should leverage experiences from these projects in diverse socio-economic contexts, identify their potentials and limitations from an integrated perspective, and share their successes and failures across the urban water sector.

KW - Anatomy

KW - Solution chemistry

KW - Wastewater

KW - Chemical structure Water treatment

UR - https://www.mendeley.com/catalogue/d87be330-bf5b-3f84-ad50-79793c2417ea/

U2 - 10.1021/acs.est.9b05222

DO - 10.1021/acs.est.9b05222

M3 - Article

SN - 0013-936X

VL - 54

SP - 5312

EP - 5322

JO - Environmental Science & Technology

JF - Environmental Science & Technology

IS - 9

ER -

A research agenda for the future of urban water management: Exploring the potential of non-grid, small-grid, and hybrid solutions

Abstract

Keywords

UN SDGs

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