The recovery of a very shallow eutrophic lake, 20 years after the control of effluent derived phosphorus

Phillips, Geoff; Kelly, Andrea; Pitt, Jo-Anne; Sanderson, Rory J.; Taylor, Eliot

doi:10.1111/j.1365-2427.2005.01434.x

Cited by 92 publications

(100 citation statements)

References 19 publications

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“…These examples show that reducing external nutrient loading does result in a return of macrophytes and an increase in species richness 20-40 years after peak nutrient loading, when macrophytes had almost disappeared (Table 1). Macrophyte return is slow and there can be a delay in recovery, where macrophytes do not yet colonise even though transparency has increased in response to reduced nutrient loading, a phenomenon also observed in other studies of nutrient reduction (Jeppesen et al, 2005a, b;Phillips et al, 2005). Furthermore, whereas macrophytes returned and species richness improved after reduction of nutrient loading, a longer term comparison shows that the species richness and macrophyte community is different from the records about a century ago, from the early 1900s, which was the start of human-induced large-scale eutrophication (Table 1).…”

Section: Restoration Measuresmentioning

confidence: 72%

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

et al. 2012

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Although many lake restoration projects have led to decreased nutrient loads and increased water transparency, the establishment or expansion of macrophytes does not immediately follow the improved abiotic conditions and it is often unclear whether vegetation with high macrophyte diversity will return. We provide an overview of the potential bottlenecks for restoration of submerged macrophyte vegetation with a high biodiversity and focus on the biotic factors, including the availability of propagules, herbivory, plant competition and the role of remnant populations. We found that the potential for restoration in many lakes is large when clear water conditions are met, even though the macrophyte community composition of the early 1900s, the start of humaninduced large-scale eutrophication in Northwestern Europe, could not be restored. However, emerging charophytes and species rich vegetation are often lost due to competition with eutrophic species. Disturbances such as herbivory can limit dominance by eutrophic species and improve macrophyte diversity. We conclude that it is imperative to study the role of propagule availability more closely as well as the biotic interactions including herbivory and plant competition. After abiotic conditions are met, these will further determine macrophyte diversity and define what exactly can be restored and what not.

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Section: Restoration Measuresmentioning

confidence: 72%

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

et al. 2012

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“…Of the limited ecological studies available, most have focused on responses of chlorophyll concentrations to nutrient load reductions. These case-studies (Carvalho and Kirika, 2003;Ferguson et al, 2008;Jeppesen et al, 2005;Moss et al, 2005;Phillips et al, 2005) all indicate strong ecological resilience to reduced in-lake phosphorus concentrations, with limited improvements observed in chlorophyll concentrations or algal blooms even following large reductions in both external loads and in-lake phosphorus concentrations. One of the reasons for ecological resilience is that even following reductions of in-lake phosphorus concentrations, phosphorus may still be in excess of plant and algal requirements and production may, therefore, be limited by other factors, such as nitrogen or light availability (Moss et al, 2005).…”

Section: Ecological Responses To Reduced Phosphorus Concentrationsmentioning

confidence: 99%

A model‐based assessment of non‐compliance of phosphorus standards for lakes in England and Wales

Duethmann

Anthony

Carvalho

et al. 2009

International Journal of River Basin Management

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High phosphorus concentrations causing eutrophication will prevent many lakes in England and Wales from reaching good ecological status by 2015 according to the EC Water Framework Directive (WFD). The aim of this study was to estimate the percentage of lakes in England and Wales that are likely to fail recently agreed WFD phosphorus standards. As measured lake phosphorus concentrations are only available for a small number of lakes a model-based approach was adopted. This involved estimating phosphorus loads from a wide range of sources including agricultural loads, sewage effluents, septic tanks, diffuse urban sources, atmospheric deposition, groundwater and bank erosion. Lake phosphorus concentrations were predicted using the Vollenweider model, and the model framework was satisfactorily tested against available observed lake concentration data. Applying the model to all lakes in England and Wales greater than 1 ha, it was estimated that under current conditions, roughly two thirds of the lakes would fail good ecological status with respect to phosphorus. According to our estimates, agricultural phosphorus loads represent the dominant source for the majority of catchments, but diffuse urban runoff also is important in many lakes and sewage effluents are the most frequent dominant source for lake catchments greater than 100 km 2 . Required reductions of phosphorus loads to increase the number of lakes achieving good ecological status and potential delays because of internal loading and biological resistances are briefly discussed.

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“…However, the response of plankton communities to nutrient reduction has sometimes been found to be weak or inconsistent in phytoplankton [27,32,33] and zooplankton [13,34,35]. Therefore, a joint effect of changes in nutrient concentrations and climate is more likely [16,36].…”

Section: Introductionmentioning

confidence: 99%

Long-Term Trends and Temporal Synchrony in Plankton Richness, Diversity and Biomass Driven by Re-Oligotrophication and Climate across 17 Danish Lakes

Özkan

Davidson

Bjerring

et al. 2016

Water

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A two-decade (1989)(1990)(1991)(1992)(1993)(1994)(1995)(1996)(1997)(1998)(1999)(2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008) time series of lake phyto-and zooplankton, water characteristics and climate in 17 Danish lakes was analysed to examine the long term changes and the effects of lake restoration efforts. The analyses of the pair-wise correlations across time series revealed a strong synchrony in climatic variables among the lakes. A significant, but weak increase in air temperature was observed and resulted in a corresponding increase in surface water temperature only in summer. Lake physico-chemical variables had weaker synchrony than climatic variables. Synchrony in water temperature and stratification was stronger than lake chemistry as the former is mostly affected by atmospheric energy flux. Synchrony in the taxonomic richness of the plankton groups and phytoplankton biomass was apparent, to a similar degree as observed for lake chemistry. The synchrony and the temporal trends in lake chemistry and plankton were more pronounced for the lakes with strong re-oligotrophication. Phytoplankton biomass decreased and plankton richness increased in these lakes, with a shift from Chlorophyta dominance towards more heterogeneous phytoplankton communities. Notably, a widespread significant positive trend in plankton richness was observed not only in lakes with strong re-oligotrophication but across all lakes. The widespread increase in plankton richness coincided with widespread decrease in phosphate and total nitrogen concentrations, as well as with the trends in climate indicating a likely joint effect of nutrient reduction and climate in driving lake plankton. However, temporal changes and synchrony as well as the recovery of richness and composition of lake plankton more coherently corresponded with the nutrient loading reduction across the Danish landscape, while the role of climate control of the lake plankton was less pronounced.

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The recovery of a very shallow eutrophic lake, 20 years after the control of effluent derived phosphorus

Cited by 92 publications

References 19 publications

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

A model‐based assessment of non‐compliance of phosphorus standards for lakes in England and Wales

Long-Term Trends and Temporal Synchrony in Plankton Richness, Diversity and Biomass Driven by Re-Oligotrophication and Climate across 17 Danish Lakes

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