Chesapeake Bay groundwater withdrawals causing sinking land, flooding risks
USGS report shows groundwater withdrawals causing sinking land that's contributing to flooding risks in the southern Chesapeake Bay region.
Dec. 10, 2013 -- According to a new report by the U.S. Geological Survey (USGS), intensive groundwater withdrawals are a major cause of the sinking land, or land subsidence, that's contributing to flooding risks among communities and coastal habitats in the southern Chesapeake Bay region.
The report suggests that changing groundwater management practices could slow or mitigate land subsidence and relative sea-level rise. Moving groundwater pumping away from high-risk areas or decreasing groundwater withdrawal rates can reduce subsidence in low-lying areas prone to flooding. These results will be used by federal and state managers to consider adaptation strategies in their efforts to restore and protect the Chesapeake Bay.
Previous USGS studies have established that the Chesapeake Bay region has the highest rates of relative sea-level rise on the East Coast. Likewise, the sea-level rise rates around the Chesapeake Bay range from 3.2 to 4.7mm/per year with 4.4 mm/yr in Norfolk. (A penny is about 1 mm thick.) Land subsidence alone causes more than half of the observed relative sea-level rise in the southern Chesapeake Bay.
"From a practical viewpoint, sea level is relative to the land surface," said Jerad Bales, acting associate director for water at USGS. "Whether the water is rising or the land is sinking, or both, the effect is the same: greater vulnerability to coastal storms and loss of important coastal habitat, both of which result in economic losses."
While there are several factors influencing land subsidence, aquifer system compaction -- caused by extensive groundwater pumping in the Virginia Coastal Plain -- is a major cause in the Norfolk area. Land subsidence has occurred around Norfolk at an average rate of 3 mm/year since 1940. Low-lying communities and critical habitats are especially vulnerable to damage from the relative sea-level rise caused by land subsidence. Communities in the southern Bay can experience increased flooding. The loss of coastal marsh and wetlands decreases the extent of specific habitat that waterfowl need to winter in the Bay region.
Continued monitoring, mapping and modeling are scientific tools needed to help natural resource managers and urban planners understand and reduce or mitigate land subsidence. Changing resource management practices in response to rising seas and sinking land will require sustained public commitment.