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Critical transitions in ecosystem state may be driven by coupled feedback mechanisms: a case study from Erhai lake, China

Critical transitions in ecosystem state may be driven by coupled feedback mechanisms: a case study from Erhai lake, China
Critical transitions in ecosystem state may be driven by coupled feedback mechanisms: a case study from Erhai lake, China
Critical transitions between ecosystem states can be triggered by relatively small external forces or internal perturbations and may show time-lagged or hysteretic recovery. Understanding the precise mechanisms of a transition is important for ecosystem management, but it is hampered by a lack of information about the preceding interactions and associated feedback between different components in an ecosystem. This paper employs a range of data, including paleolimnological, environmental monitoring and documentary sources from lake Erhai and its catchment, to investigate the ecosystem structure and dynamics across multiple trophic levels through the process of eutrophication. A long-term perspective shows the growth and decline of two distinct, but coupled, positive feedback loops: a macrophyte-loop and a phosphorus-recycling-loop. The macrophyte-loop became
weaker, and the phosphorus-recycling-loop became stronger during the process of lake eutrophication, indicating that the critical transition was propelled by the interaction of two positive feedback loops with different strengths. For lake restoration, future weakening of the phosphorus-recycling loop or a reduction in external pressures is expected to trigger macrophyte growth and eventually
produce clear water conditions, but the speed of recovery will probably depend on the rates of feedback loops and the strength of their coupling.
critical transition, eutrophication, paleolimnology, regime shift, positive feedback
2073-4441
85-99
Wang, Rong
43fad2c7-20fb-4d22-a844-2c7f2a4c092d
Dearing, John
dff37300-b8a6-4406-ad84-89aa01de03d7
Langdon, Peter
95b97671-f9fe-4884-aca6-9aa3cd1a6d7f
Wang, Rong
43fad2c7-20fb-4d22-a844-2c7f2a4c092d
Dearing, John
dff37300-b8a6-4406-ad84-89aa01de03d7
Langdon, Peter
95b97671-f9fe-4884-aca6-9aa3cd1a6d7f

Wang, Rong, Dearing, John and Langdon, Peter (2022) Critical transitions in ecosystem state may be driven by coupled feedback mechanisms: a case study from Erhai lake, China. Water, 14 (1), 85-99.

Record type: Article

Abstract

Critical transitions between ecosystem states can be triggered by relatively small external forces or internal perturbations and may show time-lagged or hysteretic recovery. Understanding the precise mechanisms of a transition is important for ecosystem management, but it is hampered by a lack of information about the preceding interactions and associated feedback between different components in an ecosystem. This paper employs a range of data, including paleolimnological, environmental monitoring and documentary sources from lake Erhai and its catchment, to investigate the ecosystem structure and dynamics across multiple trophic levels through the process of eutrophication. A long-term perspective shows the growth and decline of two distinct, but coupled, positive feedback loops: a macrophyte-loop and a phosphorus-recycling-loop. The macrophyte-loop became
weaker, and the phosphorus-recycling-loop became stronger during the process of lake eutrophication, indicating that the critical transition was propelled by the interaction of two positive feedback loops with different strengths. For lake restoration, future weakening of the phosphorus-recycling loop or a reduction in external pressures is expected to trigger macrophyte growth and eventually
produce clear water conditions, but the speed of recovery will probably depend on the rates of feedback loops and the strength of their coupling.

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water-14-00085-v2 - Version of Record
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Published date: 3 January 2022
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Keywords: critical transition, eutrophication, paleolimnology, regime shift, positive feedback

Identifiers

Local EPrints ID: 454037
URI: http://eprints.soton.ac.uk/id/eprint/454037
ISSN: 2073-4441
PURE UUID: f6490ef1-2fed-45a0-8430-0d972356be52
ORCID for John Dearing: ORCID iD orcid.org/0000-0002-1466-9640
ORCID for Peter Langdon: ORCID iD orcid.org/0000-0003-2724-2643

Catalogue record

Date deposited: 27 Jan 2022 18:52
Last modified: 17 Mar 2024 02:59

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Contributors

Author: Rong Wang
Author: John Dearing ORCID iD
Author: Peter Langdon ORCID iD

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