We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Challenge to Lake Ecosystems: Changes in Thermal Structure Triggered by Climate Change
Summary
This review examines how climate change is altering the temperature structure of lakes, with warmer surface waters creating stronger separation between upper and lower layers. This intensified layering can trap pollutants in deeper water and promote harmful algal blooms near the surface. While not directly about microplastics, these changing lake dynamics affect how all pollutants, including microplastics, are distributed and transported in freshwater ecosystems.
Human activities, global warming, frequent extreme weather events, and changes in atmospheric composition affect the solar radiation reaching the Earth’s surface, affect mass and heat transfer at the air–water interface, and induce oscillations in wind-driven internal waves. This leads to changes in the spatiotemporal characteristics of thermal stratification in lakes, altering lake circulation patterns and vertical mass transfer. However, thermal stratification structures are often overlooked. The intensification of lake thermal stratification due to warming may lead to increased release of bottom pollutants, spreading through the dynamic behavior of the thermocline to the epilimnion. Moreover, the increased heat storage is beneficial for the growth and development of certain phytoplankton, resulting in rapid transitions of the original steady state of lakes. Consequently, water quality deterioration, ecological degradation, and declining biodiversity may occur. Conventional surface water monitoring may not provide comprehensive, accurate, and timely assessments. Model simulations can better predict future thermal stratification behaviors, reducing financial burdens, providing more refined assessments, and thus preventing subsequent environmental issues.
Sign in to start a discussion.
More Papers Like This
Review of microplastics in lakes: sources, distribution characteristics, and environmental effects
This review analyzes microplastic pollution in lakes worldwide and finds that contamination levels are higher in shallower lakes near populated areas with more human activity. Microplastics accumulate heavily in lake sediments and can also be trapped in seasonal ice, only to be released during warming periods. Since many communities rely on lakes for drinking water and fishing, understanding how microplastics concentrate in these freshwater systems is critical for protecting public health.
How climate change and eutrophication interact with microplastic pollution and sediment resuspension in shallow lakes: A review
This review examines how climate change and eutrophication interact with and potentially amplify microplastic pollution and sediment resuspension in shallow lake ecosystems. The authors identify compounding threats to lake health and call for integrated research that considers these stressors together rather than in isolation.
Climate change and microplastic pollution in aquatic ecosystems: ecological and societal consequences
This review examines how climate change amplifies the ecological and societal impacts of microplastic pollution in aquatic ecosystems. The study suggests that rising temperatures, extreme weather events, and altered precipitation patterns accelerate plastic fragmentation and dispersal, creating compounding effects on water quality, biodiversity, and coastal communities.
Microplastic Pollution in Surface Waters and Sediments of Urban Lake
This book chapter reviews microplastic pollution in urban lake surface waters and sediments, describing sources, distribution patterns, and the ecological consequences of MP accumulation in these widely used but understudied freshwater habitats.
Microplastic pollution in lakes: Sources, impact, and solutions
This review comprehensively covers the sources, pathways, ecological impacts, and remediation strategies for microplastic pollution in freshwater lakes, highlighting how particles from urban runoff, wastewater, and atmospheric deposition accumulate in lake ecosystems and transfer into food webs.