Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures

Lauren McPhillips; Marta Berbés-Blázquez; Rebecca Hale; Tamara K. Harms; Vanya Bisht; Liliana Caughman; Sandra M. Clinton; Elizabeth Cook; Xiaoli Dong; Jennifer Edmonds; Sarah Gergel; Rosa Gómez; Kristina Hopkins; David M. Iwaniec; Yeowon Kim; Amanda Kuhn; Libby Larson; David B. Lewis; Eugenía Martí; Monica Palta; W. John Roach; Lin Ye

doi:10.1016/j.jhydrol.2022.128841

Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures

Lauren McPhillips, Marta Berbés-Blázquez, Rebecca Hale, Tamara K. Harms, Vanya Bisht, Liliana Caughman, Sandra M. Clinton, Elizabeth Cook, Xiaoli Dong, Jennifer Edmonds, Sarah Gergel, Rosa Gómez, Kristina Hopkins, David M. Iwaniec, Yeowon Kim, Amanda Kuhn, Libby Larson, David B. Lewis, Eugenía Martí, Monica PaltaW. John Roach, Lin Ye

Research output: Contribution to journal › Review article › peer-review

Abstract

The hydrology and aquatic ecology of arid environments has long been understudied relative to temperate regions. Yet spatially and temporally intermittent and ephemeral waters characterized by flashy hydrographs typify arid regions that comprise a substantial proportion of the Earth. Additionally, drought, intense storms, and human modification of landscapes increasingly affect many temperate regions, resulting in hydrologic regimes more similar to aridlands. Here we review the contributions of Dr. Nancy Grimm to aridland hydrology and ecology, and applications of these insights to urban ecosystems and resilience of social-ecological-technological systems. Grimm catalyzed study of nitrogen cycling in streams and characterized feedbacks between surface water-groundwater exchange, nitrogen transformations, and aquatic biota. In aridlands, outcomes of these interactions depend on short- and long-term variation in the hydrologic regime. Grimm and colleagues applied hydrological and biogeochemical insights gained from study of aridland streams to urban ecosystems, integrating engineering, social and behavioral sciences, and geography. These studies evolved from characterizing the spatial heterogeneity of urban systems (i.e., watersheds, novel aquatic systems) and its influence on nutrient dynamics to an approach that evaluated human decision-making as a driver of disturbance regimes and changes in ecosystem function. Finally, Grimm and colleagues have applied principles of urban ecology to look toward the future of cities, considering scenarios of sustainable and resilient futures. We identify cross-cutting themes and approaches that have motivated discoveries across Grimm's multi-decadal career, including spatial and temporal heterogeneity, hydrologic connectivity and regime, disturbance, systems thinking, and resilience. Finally, we emphasize Grimm's broad contributions to science via support of long-term research, dedication to mentoring, and extensive collaborations that facilitated transdisciplinary research.

Original language	English (US)
Article number	128841
Journal	Journal of Hydrology
Volume	616
DOIs	https://doi.org/10.1016/j.jhydrol.2022.128841
State	Published - Jan 2023

All Science Journal Classification (ASJC) codes

Water Science and Technology

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10.1016/j.jhydrol.2022.128841

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McPhillips, L., Berbés-Blázquez, M., Hale, R., Harms, T. K., Bisht, V., Caughman, L., Clinton, S. M., Cook, E., Dong, X., Edmonds, J., Gergel, S., Gómez, R., Hopkins, K., Iwaniec, D. M., Kim, Y., Kuhn, A., Larson, L., Lewis, D. B., Martí, E., ... Ye, L. (2023). Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures. Journal of Hydrology, 616, [128841]. https://doi.org/10.1016/j.jhydrol.2022.128841

@article{97fd8c0ee9144320981cf5e6b9bb395c,

title = "Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures",

abstract = "The hydrology and aquatic ecology of arid environments has long been understudied relative to temperate regions. Yet spatially and temporally intermittent and ephemeral waters characterized by flashy hydrographs typify arid regions that comprise a substantial proportion of the Earth. Additionally, drought, intense storms, and human modification of landscapes increasingly affect many temperate regions, resulting in hydrologic regimes more similar to aridlands. Here we review the contributions of Dr. Nancy Grimm to aridland hydrology and ecology, and applications of these insights to urban ecosystems and resilience of social-ecological-technological systems. Grimm catalyzed study of nitrogen cycling in streams and characterized feedbacks between surface water-groundwater exchange, nitrogen transformations, and aquatic biota. In aridlands, outcomes of these interactions depend on short- and long-term variation in the hydrologic regime. Grimm and colleagues applied hydrological and biogeochemical insights gained from study of aridland streams to urban ecosystems, integrating engineering, social and behavioral sciences, and geography. These studies evolved from characterizing the spatial heterogeneity of urban systems (i.e., watersheds, novel aquatic systems) and its influence on nutrient dynamics to an approach that evaluated human decision-making as a driver of disturbance regimes and changes in ecosystem function. Finally, Grimm and colleagues have applied principles of urban ecology to look toward the future of cities, considering scenarios of sustainable and resilient futures. We identify cross-cutting themes and approaches that have motivated discoveries across Grimm's multi-decadal career, including spatial and temporal heterogeneity, hydrologic connectivity and regime, disturbance, systems thinking, and resilience. Finally, we emphasize Grimm's broad contributions to science via support of long-term research, dedication to mentoring, and extensive collaborations that facilitated transdisciplinary research.",

author = "Lauren McPhillips and Marta Berb{\'e}s-Bl{\'a}zquez and Rebecca Hale and Harms, {Tamara K.} and Vanya Bisht and Liliana Caughman and Clinton, {Sandra M.} and Elizabeth Cook and Xiaoli Dong and Jennifer Edmonds and Sarah Gergel and Rosa G{\'o}mez and Kristina Hopkins and Iwaniec, {David M.} and Yeowon Kim and Amanda Kuhn and Libby Larson and Lewis, {David B.} and Eugen{\'i}a Mart{\'i} and Monica Palta and {John Roach}, W. and Lin Ye",

note = "Funding Information: We also acknowledge the extensive funding from a variety of sources that has supported Nancy Grimm{\textquoteright}s research and student training efforts over the last several decades, most extensively from the US National Science Foundation. We note several recent NSF awards which supported several co-authors listed here and/or the development of ideas articulated in this article: 1832016 (CAP LTER IV) 1444755 (URExSRN), 1927468 (NATURA). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Funding Information: Included here is a list of {\textquoteleft}co-signatories{\textquoteright}- former Grimm mentees who wished to indicate their support of the manuscript concept (in alphabetical order): David Casagrande, Michele Clark, Stephen Elser, Susanne Grossman-Clarke, Amalia Handler, Madhusudan Katti, Marina Lauck, Katherine Lohse, Melissa McHale, Andr{\'e}s Mill{\'a}n, Jorge Ramos, Jason Sauer, Rich Sheibley, Ryan Sponseller, Emily Stanley, Josefa Velasco Garc{\'i}a. While the authors and co-signatories of this review represent a large proportion of Nancy Grimm's mentees, we acknowledge additional trainees not listed, in addition to the diverse worldwide network of collaborators for their contributions to the body of work reviewed here. We also acknowledge the extensive funding from a variety of sources that has supported Nancy Grimm's research and student training efforts over the last several decades, most extensively from the US National Science Foundation. We note several recent NSF awards which supported several co-authors listed here and/or the development of ideas articulated in this article: 1832016 (CAP LTER IV) 1444755 (URExSRN), 1927468 (NATURA). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Funding Information: Studies at Sycamore Creek contributed to growing recognition of N limitation in streams (e.g., Naiman and Melillo, 1984; Triska et al., 1984 ) that was leveraged to support the Lotic Intersite Nitrogen eXperiment (LINX). LINX generated cross-biome insights into N cycling in streams by convening one of the largest collaborative groups funded by the Division of Environmental Biology (US National Science Foundation) at its establishment in 1996 ( LINX collaborators, 2014 ). In its first stage, the LINX project applied a novel stable isotope tracer approach to quantify retention and transformation of ammonium, finding high capacity for N retention in headwater streams due to assimilation by algae and microbial heterotrophs ( Peterson et al., 2001; Webster et al., 2003 ). The tracer approach also demonstrated flow of N from aquatic to terrestrial food webs ( Sanzone et al., 2003 ). A second phase addressed nitrate retention and denitrification across streams draining wildland, urban, and agricultural land covers. A decline in retention efficiency with N concentration and in simplified channels of urban streams implied reduced capacity for N retention by stream networks subject to anthropogenic N loading and channel modification ( Grimm et al., 2005; Martin et al., 2011; Mulholland et al., 2008 ). Grimm contributed to the vision and momentum of LINX while also establishing several mentees as equal collaborators in the project. Publisher Copyright: {\textcopyright} 2022 Elsevier B.V.",

year = "2023",

month = jan,

doi = "10.1016/j.jhydrol.2022.128841",

language = "English (US)",

volume = "616",

journal = "Journal of Hydrology",

issn = "0022-1694",

publisher = "Elsevier",

}

McPhillips, L, Berbés-Blázquez, M, Hale, R, Harms, TK, Bisht, V, Caughman, L, Clinton, SM, Cook, E, Dong, X, Edmonds, J, Gergel, S, Gómez, R, Hopkins, K, Iwaniec, DM, Kim, Y, Kuhn, A, Larson, L, Lewis, DB, Martí, E, Palta, M, John Roach, W & Ye, L 2023, 'Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures', Journal of Hydrology, vol. 616, 128841. https://doi.org/10.1016/j.jhydrol.2022.128841

TY - JOUR

T1 - Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures

AU - McPhillips, Lauren

AU - Berbés-Blázquez, Marta

AU - Hale, Rebecca

AU - Harms, Tamara K.

AU - Bisht, Vanya

AU - Caughman, Liliana

AU - Clinton, Sandra M.

AU - Cook, Elizabeth

AU - Dong, Xiaoli

AU - Edmonds, Jennifer

AU - Gergel, Sarah

AU - Gómez, Rosa

AU - Hopkins, Kristina

AU - Iwaniec, David M.

AU - Kim, Yeowon

AU - Kuhn, Amanda

AU - Larson, Libby

AU - Lewis, David B.

AU - Martí, Eugenía

AU - Palta, Monica

AU - John Roach, W.

AU - Ye, Lin

N1 - Funding Information: We also acknowledge the extensive funding from a variety of sources that has supported Nancy Grimm’s research and student training efforts over the last several decades, most extensively from the US National Science Foundation. We note several recent NSF awards which supported several co-authors listed here and/or the development of ideas articulated in this article: 1832016 (CAP LTER IV) 1444755 (URExSRN), 1927468 (NATURA). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Funding Information: Included here is a list of ‘co-signatories’- former Grimm mentees who wished to indicate their support of the manuscript concept (in alphabetical order): David Casagrande, Michele Clark, Stephen Elser, Susanne Grossman-Clarke, Amalia Handler, Madhusudan Katti, Marina Lauck, Katherine Lohse, Melissa McHale, Andrés Millán, Jorge Ramos, Jason Sauer, Rich Sheibley, Ryan Sponseller, Emily Stanley, Josefa Velasco García. While the authors and co-signatories of this review represent a large proportion of Nancy Grimm's mentees, we acknowledge additional trainees not listed, in addition to the diverse worldwide network of collaborators for their contributions to the body of work reviewed here. We also acknowledge the extensive funding from a variety of sources that has supported Nancy Grimm's research and student training efforts over the last several decades, most extensively from the US National Science Foundation. We note several recent NSF awards which supported several co-authors listed here and/or the development of ideas articulated in this article: 1832016 (CAP LTER IV) 1444755 (URExSRN), 1927468 (NATURA). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Funding Information: Studies at Sycamore Creek contributed to growing recognition of N limitation in streams (e.g., Naiman and Melillo, 1984; Triska et al., 1984 ) that was leveraged to support the Lotic Intersite Nitrogen eXperiment (LINX). LINX generated cross-biome insights into N cycling in streams by convening one of the largest collaborative groups funded by the Division of Environmental Biology (US National Science Foundation) at its establishment in 1996 ( LINX collaborators, 2014 ). In its first stage, the LINX project applied a novel stable isotope tracer approach to quantify retention and transformation of ammonium, finding high capacity for N retention in headwater streams due to assimilation by algae and microbial heterotrophs ( Peterson et al., 2001; Webster et al., 2003 ). The tracer approach also demonstrated flow of N from aquatic to terrestrial food webs ( Sanzone et al., 2003 ). A second phase addressed nitrate retention and denitrification across streams draining wildland, urban, and agricultural land covers. A decline in retention efficiency with N concentration and in simplified channels of urban streams implied reduced capacity for N retention by stream networks subject to anthropogenic N loading and channel modification ( Grimm et al., 2005; Martin et al., 2011; Mulholland et al., 2008 ). Grimm contributed to the vision and momentum of LINX while also establishing several mentees as equal collaborators in the project. Publisher Copyright: © 2022 Elsevier B.V.

PY - 2023/1

Y1 - 2023/1

N2 - The hydrology and aquatic ecology of arid environments has long been understudied relative to temperate regions. Yet spatially and temporally intermittent and ephemeral waters characterized by flashy hydrographs typify arid regions that comprise a substantial proportion of the Earth. Additionally, drought, intense storms, and human modification of landscapes increasingly affect many temperate regions, resulting in hydrologic regimes more similar to aridlands. Here we review the contributions of Dr. Nancy Grimm to aridland hydrology and ecology, and applications of these insights to urban ecosystems and resilience of social-ecological-technological systems. Grimm catalyzed study of nitrogen cycling in streams and characterized feedbacks between surface water-groundwater exchange, nitrogen transformations, and aquatic biota. In aridlands, outcomes of these interactions depend on short- and long-term variation in the hydrologic regime. Grimm and colleagues applied hydrological and biogeochemical insights gained from study of aridland streams to urban ecosystems, integrating engineering, social and behavioral sciences, and geography. These studies evolved from characterizing the spatial heterogeneity of urban systems (i.e., watersheds, novel aquatic systems) and its influence on nutrient dynamics to an approach that evaluated human decision-making as a driver of disturbance regimes and changes in ecosystem function. Finally, Grimm and colleagues have applied principles of urban ecology to look toward the future of cities, considering scenarios of sustainable and resilient futures. We identify cross-cutting themes and approaches that have motivated discoveries across Grimm's multi-decadal career, including spatial and temporal heterogeneity, hydrologic connectivity and regime, disturbance, systems thinking, and resilience. Finally, we emphasize Grimm's broad contributions to science via support of long-term research, dedication to mentoring, and extensive collaborations that facilitated transdisciplinary research.

AB - The hydrology and aquatic ecology of arid environments has long been understudied relative to temperate regions. Yet spatially and temporally intermittent and ephemeral waters characterized by flashy hydrographs typify arid regions that comprise a substantial proportion of the Earth. Additionally, drought, intense storms, and human modification of landscapes increasingly affect many temperate regions, resulting in hydrologic regimes more similar to aridlands. Here we review the contributions of Dr. Nancy Grimm to aridland hydrology and ecology, and applications of these insights to urban ecosystems and resilience of social-ecological-technological systems. Grimm catalyzed study of nitrogen cycling in streams and characterized feedbacks between surface water-groundwater exchange, nitrogen transformations, and aquatic biota. In aridlands, outcomes of these interactions depend on short- and long-term variation in the hydrologic regime. Grimm and colleagues applied hydrological and biogeochemical insights gained from study of aridland streams to urban ecosystems, integrating engineering, social and behavioral sciences, and geography. These studies evolved from characterizing the spatial heterogeneity of urban systems (i.e., watersheds, novel aquatic systems) and its influence on nutrient dynamics to an approach that evaluated human decision-making as a driver of disturbance regimes and changes in ecosystem function. Finally, Grimm and colleagues have applied principles of urban ecology to look toward the future of cities, considering scenarios of sustainable and resilient futures. We identify cross-cutting themes and approaches that have motivated discoveries across Grimm's multi-decadal career, including spatial and temporal heterogeneity, hydrologic connectivity and regime, disturbance, systems thinking, and resilience. Finally, we emphasize Grimm's broad contributions to science via support of long-term research, dedication to mentoring, and extensive collaborations that facilitated transdisciplinary research.

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U2 - 10.1016/j.jhydrol.2022.128841

DO - 10.1016/j.jhydrol.2022.128841

M3 - Review article

AN - SCOPUS:85143593652

SN - 0022-1694

VL - 616

JO - Journal of Hydrology

JF - Journal of Hydrology

M1 - 128841

ER -

Learning from arid and urban aquatic ecosystems to inform more sustainable and resilient futures

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