Phosphorus mitigation remains critical in water protection

A review and meta-analysis from one of China's most eutrophicated lakes

Kai Yan, Zengwei Yuan, Stefanie Goldberg, Wei Gao, Anne Ostermann, Jianchu Xu, Fusuo Zhang, James Elser

Research output: Contribution to journalReview article

Abstract

The processes of urbanization and industrialization within geological phosphorus-rich mountains (GPMn) have resulted in water degradation within southwest China. Lake Dianchi, one of the most eutrophicated lakes in China, has epitomized this issue. Clear understandings of phosphorus (P) mitigation efforts, the evolution of P budgets, and possible risks in the Dianchi system will benefit future eutrophication control, providing valuable lessons for other plateau freshwater lakes. In this study, we applied systematic review methodology to investigate the above questions, and then compared the results with other lakes worldwide. Generally, meta-analytical approaches have indicated P levels remain a key factor in causing algal blooms. Post-2015, the P budget of the Dianchi system, especially in Caohai section, was modified. However, it's still experiencing high pressures from P enrichment (Caohai: 0.4 mg·l−1; Waihai: 0.2 mg·l−1). The flux of P in Dianchi remains high, both through the external P load (556 ton·a−1), and an internal cycle (304 ton·a−1 associated with the absorption, deposition and removal of algae biomass; and 380 ton·a−1 associated with sediment exchange). Meanwhile, significant P retention has been observed in the lake, in particular within the Waihai section (211 ton·a−1). Currently, water diversion (from external watersheds), sewage diversion, and sediment-dredging projects have benefited Dianchi. However, continuous urbanization and GPMn ecological degradation could introduce hundreds of tons of additional P, leading to subsequent algal blooms. Furthermore, beyond Lake Dianchi, other lakes and reservoirs in southwest China are facing similar issues regarding P mitigation, especially in GPMn regions, though corresponding knowledge is still limited. Therefore, effective and flexible sub-regional protection strategies and research related to external and internal P mitigations have become key requirements for Lake Dianchi management. Meanwhile, ecologically sensitive approaches to GPMn regions, as well as city development within basin and market driven treatments, should be incorporated into regional water source protection for southwest China.

Original languageEnglish (US)
Pages (from-to)1336-1347
Number of pages12
JournalScience of the Total Environment
Volume689
DOIs
StatePublished - Nov 1 2019

Fingerprint

meta-analysis
Phosphorus
Lakes
mitigation
phosphorus
Water
lake
River diversion
mountain region
urbanization
Sediments
algal bloom
Degradation
market development
degradation
Eutrophication
mountain
water protection
Dredging
Sewage

Keywords

  • Bayesian hierarchical model
  • Geological phosphorus-rich mountains
  • Lake Dianchi
  • Markov chain Monte Carlo simulation
  • Phosphorus budget
  • Watershed management

ASJC Scopus subject areas

  • Environmental Engineering
  • Environmental Chemistry
  • Waste Management and Disposal
  • Pollution

Cite this

Phosphorus mitigation remains critical in water protection : A review and meta-analysis from one of China's most eutrophicated lakes. / Yan, Kai; Yuan, Zengwei; Goldberg, Stefanie; Gao, Wei; Ostermann, Anne; Xu, Jianchu; Zhang, Fusuo; Elser, James.

In: Science of the Total Environment, Vol. 689, 01.11.2019, p. 1336-1347.

Research output: Contribution to journalReview article

Yan, Kai ; Yuan, Zengwei ; Goldberg, Stefanie ; Gao, Wei ; Ostermann, Anne ; Xu, Jianchu ; Zhang, Fusuo ; Elser, James. / Phosphorus mitigation remains critical in water protection : A review and meta-analysis from one of China's most eutrophicated lakes. In: Science of the Total Environment. 2019 ; Vol. 689. pp. 1336-1347.
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abstract = "The processes of urbanization and industrialization within geological phosphorus-rich mountains (GPMn) have resulted in water degradation within southwest China. Lake Dianchi, one of the most eutrophicated lakes in China, has epitomized this issue. Clear understandings of phosphorus (P) mitigation efforts, the evolution of P budgets, and possible risks in the Dianchi system will benefit future eutrophication control, providing valuable lessons for other plateau freshwater lakes. In this study, we applied systematic review methodology to investigate the above questions, and then compared the results with other lakes worldwide. Generally, meta-analytical approaches have indicated P levels remain a key factor in causing algal blooms. Post-2015, the P budget of the Dianchi system, especially in Caohai section, was modified. However, it's still experiencing high pressures from P enrichment (Caohai: 0.4 mg·l−1; Waihai: 0.2 mg·l−1). The flux of P in Dianchi remains high, both through the external P load (556 ton·a−1), and an internal cycle (304 ton·a−1 associated with the absorption, deposition and removal of algae biomass; and 380 ton·a−1 associated with sediment exchange). Meanwhile, significant P retention has been observed in the lake, in particular within the Waihai section (211 ton·a−1). Currently, water diversion (from external watersheds), sewage diversion, and sediment-dredging projects have benefited Dianchi. However, continuous urbanization and GPMn ecological degradation could introduce hundreds of tons of additional P, leading to subsequent algal blooms. Furthermore, beyond Lake Dianchi, other lakes and reservoirs in southwest China are facing similar issues regarding P mitigation, especially in GPMn regions, though corresponding knowledge is still limited. Therefore, effective and flexible sub-regional protection strategies and research related to external and internal P mitigations have become key requirements for Lake Dianchi management. Meanwhile, ecologically sensitive approaches to GPMn regions, as well as city development within basin and market driven treatments, should be incorporated into regional water source protection for southwest China.",
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AU - Xu, Jianchu

AU - Zhang, Fusuo

AU - Elser, James

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N2 - The processes of urbanization and industrialization within geological phosphorus-rich mountains (GPMn) have resulted in water degradation within southwest China. Lake Dianchi, one of the most eutrophicated lakes in China, has epitomized this issue. Clear understandings of phosphorus (P) mitigation efforts, the evolution of P budgets, and possible risks in the Dianchi system will benefit future eutrophication control, providing valuable lessons for other plateau freshwater lakes. In this study, we applied systematic review methodology to investigate the above questions, and then compared the results with other lakes worldwide. Generally, meta-analytical approaches have indicated P levels remain a key factor in causing algal blooms. Post-2015, the P budget of the Dianchi system, especially in Caohai section, was modified. However, it's still experiencing high pressures from P enrichment (Caohai: 0.4 mg·l−1; Waihai: 0.2 mg·l−1). The flux of P in Dianchi remains high, both through the external P load (556 ton·a−1), and an internal cycle (304 ton·a−1 associated with the absorption, deposition and removal of algae biomass; and 380 ton·a−1 associated with sediment exchange). Meanwhile, significant P retention has been observed in the lake, in particular within the Waihai section (211 ton·a−1). Currently, water diversion (from external watersheds), sewage diversion, and sediment-dredging projects have benefited Dianchi. However, continuous urbanization and GPMn ecological degradation could introduce hundreds of tons of additional P, leading to subsequent algal blooms. Furthermore, beyond Lake Dianchi, other lakes and reservoirs in southwest China are facing similar issues regarding P mitigation, especially in GPMn regions, though corresponding knowledge is still limited. Therefore, effective and flexible sub-regional protection strategies and research related to external and internal P mitigations have become key requirements for Lake Dianchi management. Meanwhile, ecologically sensitive approaches to GPMn regions, as well as city development within basin and market driven treatments, should be incorporated into regional water source protection for southwest China.

AB - The processes of urbanization and industrialization within geological phosphorus-rich mountains (GPMn) have resulted in water degradation within southwest China. Lake Dianchi, one of the most eutrophicated lakes in China, has epitomized this issue. Clear understandings of phosphorus (P) mitigation efforts, the evolution of P budgets, and possible risks in the Dianchi system will benefit future eutrophication control, providing valuable lessons for other plateau freshwater lakes. In this study, we applied systematic review methodology to investigate the above questions, and then compared the results with other lakes worldwide. Generally, meta-analytical approaches have indicated P levels remain a key factor in causing algal blooms. Post-2015, the P budget of the Dianchi system, especially in Caohai section, was modified. However, it's still experiencing high pressures from P enrichment (Caohai: 0.4 mg·l−1; Waihai: 0.2 mg·l−1). The flux of P in Dianchi remains high, both through the external P load (556 ton·a−1), and an internal cycle (304 ton·a−1 associated with the absorption, deposition and removal of algae biomass; and 380 ton·a−1 associated with sediment exchange). Meanwhile, significant P retention has been observed in the lake, in particular within the Waihai section (211 ton·a−1). Currently, water diversion (from external watersheds), sewage diversion, and sediment-dredging projects have benefited Dianchi. However, continuous urbanization and GPMn ecological degradation could introduce hundreds of tons of additional P, leading to subsequent algal blooms. Furthermore, beyond Lake Dianchi, other lakes and reservoirs in southwest China are facing similar issues regarding P mitigation, especially in GPMn regions, though corresponding knowledge is still limited. Therefore, effective and flexible sub-regional protection strategies and research related to external and internal P mitigations have become key requirements for Lake Dianchi management. Meanwhile, ecologically sensitive approaches to GPMn regions, as well as city development within basin and market driven treatments, should be incorporated into regional water source protection for southwest China.

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