TY - JOUR
T1 - The plant ecology of nature-based solutions for people, biodiversity and climate
AU - Buckley, Yvonne M.
AU - Austin, Amy
AU - Bardgett, Richard
AU - Catford, Jane A.
AU - Hector, Andy
AU - Iler, Amy
AU - Mariotte, Pierre
N1 - Publisher Copyright:
© 2024 The Author(s). Journal of Ecology © 2024 British Ecological Society.
PY - 2024
Y1 - 2024
N2 - Integrated solutions to the climate and biodiversity crises—together with other global sustainability challenges—include the identification, design and implementation of nature-based solutions (NbS). Living organisms mediate biogeochemical cycles and greenhouse gas fluxes from land and sea, and provide NbS to both climate change mitigation and adaptation. Plants, as the primary producers in ecosystems, lie at the heart of NbS. Plant ecology provides the foundation for developing and evaluating NbS based on an understanding of the ecological processes that underlie ecosystem service flow to people. In this Special Feature, we provide a collection of mini-reviews that presents concise and focused analysis of the plant ecology of NbS. The mini-reviews highlight key insights, challenges and opportunities for future research. The development of NbS that target specific ecosystem functions (e.g. carbon storage), or aim at increasing ecosystem resilience against perturbations (e.g. those associated with climate change), requires unification of ecological theory from areas such as biodiversity-ecosystem function, plant–animal interactions, resilience and functional traits of organisms. Synthesis. Plant ecology and nature-based solutions (NbS) research are complementary. Plant ecology can inform the design and management of effective NbS, and provide insights for the creation of novel ecosystems that provide NbS; while learning from the implementation of NbS can progress theory. To deploy NbS at the speed and scale needed to mitigate and adapt to climate change, we must rapidly integrate ecological concepts into the design of NbS. At the same time, the design and deployment of NbS in different ecological contexts provides an unprecedented opportunity to learn how performances of individual NbS sites can be explained in an integrated way, leading to the development of general concepts. Ultimately, a mechanistic understanding of how plants and their functional traits contribute to ecosystem function and service provision is critical for the design, verification of benefits from and avoidance of adverse effects of NbS.
AB - Integrated solutions to the climate and biodiversity crises—together with other global sustainability challenges—include the identification, design and implementation of nature-based solutions (NbS). Living organisms mediate biogeochemical cycles and greenhouse gas fluxes from land and sea, and provide NbS to both climate change mitigation and adaptation. Plants, as the primary producers in ecosystems, lie at the heart of NbS. Plant ecology provides the foundation for developing and evaluating NbS based on an understanding of the ecological processes that underlie ecosystem service flow to people. In this Special Feature, we provide a collection of mini-reviews that presents concise and focused analysis of the plant ecology of NbS. The mini-reviews highlight key insights, challenges and opportunities for future research. The development of NbS that target specific ecosystem functions (e.g. carbon storage), or aim at increasing ecosystem resilience against perturbations (e.g. those associated with climate change), requires unification of ecological theory from areas such as biodiversity-ecosystem function, plant–animal interactions, resilience and functional traits of organisms. Synthesis. Plant ecology and nature-based solutions (NbS) research are complementary. Plant ecology can inform the design and management of effective NbS, and provide insights for the creation of novel ecosystems that provide NbS; while learning from the implementation of NbS can progress theory. To deploy NbS at the speed and scale needed to mitigate and adapt to climate change, we must rapidly integrate ecological concepts into the design of NbS. At the same time, the design and deployment of NbS in different ecological contexts provides an unprecedented opportunity to learn how performances of individual NbS sites can be explained in an integrated way, leading to the development of general concepts. Ultimately, a mechanistic understanding of how plants and their functional traits contribute to ecosystem function and service provision is critical for the design, verification of benefits from and avoidance of adverse effects of NbS.
KW - applied ecology
KW - biodiversity
KW - ecological theory
KW - ecosystem function and services
KW - ecosystem-based approach
KW - global change ecology
KW - multi-trophic interactions
KW - natural climate solution
KW - plant-climate interactions
UR - http://www.scopus.com/inward/record.url?scp=85206979606&partnerID=8YFLogxK
U2 - 10.1111/1365-2745.14441
DO - 10.1111/1365-2745.14441
M3 - Editorial
AN - SCOPUS:85206979606
SN - 0022-0477
JO - Journal of Ecology
JF - Journal of Ecology
ER -