Abstract
The influence of sea level rise and warming on circulation and water quality of the Chesapeake Bay under projected climate conditions in 2050 were estimated by computer simulation. Four estuarine circulation scenarios in the estuary were run using the same watershed load in 1991-2000 period. They are, 1) the Base Scenario, which represents the current climate condition, 2) a Sea Level Rise Scenario, 3) a Warming Scenario, and 4) a combined Sea Level Rise and Warming Scenario. With a 1.6-1.9°C increase in monthly air temperatures in the Warming Scenario, water temperature in the Bay is estimated to increase by 0.8-1°C. Summer average anoxic volume is estimated to increase 1.4 percent compared to the Base Scenario, because of an increase in algal blooms in the spring and summer, promotion of oxygen consumptive processes, and an increase of stratification. However, a 0.5-meter Sea Level Rise Scenario results in a 12 percent reduction of anoxic volume. This is mainly due to increased estuarine circulation that promotes oxygen-rich sea water intrusion in lower layers. The combined Sea Level Rise and Warming Scenario results in a 10.8 percent reduction of anoxic volume. Global warming increases precipitation and consequently increases nutrient loads from the watershed by approximately 5-7 percent. A scenario that used a 10 percent increase in watershed loads and current estuarine circulation patterns yielded a 19 percent increase in summer anoxic volume, while a scenario that used a 10 percent increase in watershed loads and modified estuarine circulation patterns by the aforementioned sea level rise and warming yielded a 6 percent increase in summer anoxic volume. Impacts on phytoplankton, sediments, and water clarity were also analysed.
Highlights
To protect the water quality and ecosystems of the Chesapeake Bay a TMDL policy was enacted by the USEPA in December of 2010 [1]
Influence on water quality by combined sea level rise and warming The summer anoxic volume in the combined Sea Level Rise and Warming (SLR+GW) Scenario is 11.7 percent less than the Base Scenario, but is slightly greater than the Sea Level Rise Scenario. These findings suggest that the dissolved oxygen (DO) change in the Sea Level Rise and Warming Scenario compared to the Base Scenario is mainly influenced by sea level rise, while the influence of warming is small
In a projected warming condition of 2050 which employs an ensemble of GCMs estimating a 1.51.9oC increase in monthly air temperatures, the water temperature in the Chesapeake Bay is estimated to increase by about 0.8-1oC
Summary
To protect the water quality and ecosystems of the Chesapeake Bay a TMDL (total maximum daily load) policy was enacted by the USEPA in December of 2010 [1]. Published under licence by IOP Publishing Ltd doi:10.1088/1755-1315/82/1/012001 changing climate on Chesapeake Bay water quality and living resources. The assessment will include projected changes in land use, precipitation, air temperature, water temperature, sea level rise, wetland loss, and water quality in the tidal Bay for 2025 and 2050. The climate change analysis will use the same methodology as that employed in the Chesapeake 2010 TMDL assessment, which applies the WQSTM estuarine model to estimate the influence exerted upon Chesapeake Bay circulation and water quality due to changed climate conditions. This study only involves the impact on water quality due to sea level rise and temperature change, as well as changes in watershed loads due to altered precipitation and temperature in a projected 2050 climate condition
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