Large dead zones predicted for Gulf, Chesapeake Bay

Record-setting "dead zones" in the Gulf of Mexico and Chesapeake Bay appear likely this summer, according to new forecasts from a University of Michigan researcher.

Donald Scavia, a professor at the U-M School of Natural Resources and Environment (SNRE), makes the annual forecasts using models driven by nutrient load estimates from the U.S. Geological Survey.

In this year's Chesapeake Bay Hypoxic Volume Forecast, Scavia predicts a summer hypoxic volume of 9.9 cubic kilometers (2.4 cubic miles), the sixth-highest on record. If the upper value of the forecast range of 12.3 cubic kilometers (3 cubic miles) is reached, it will be the highest on record. The Bay is about 200 miles long on the East Coast and stretches from Maryland to Virginia. It supports thousands of species of plants, fish and animals. The Bay's oxygen levels are critical in determining the health of its ecosystem.

Given recent massive flooding of cities and farms in the Mississippi River basin, the Gulf of Mexico Hypoxia Area Forecast is for the dead zone to cover between 21,500 and 22,500 square kilometers (8,400-8,800 square miles) of bottom waters along the Louisiana-Texas coast. If the prediction bears out, it will be the largest on record.

"The growth of these dead zones is an ecological time bomb," said Scavia, who is also director of the Michigan Sea Grant program based at SNRE. "Without determined local, regional, and national efforts to control them, we are putting major fisheries at risk." According to Scavia, the best way to shrink the dead zones is to reduce the amount of nitrogen and phosphorous flowing into these water basins.

Hypoxia refers to the loss of oxygen in water, which then leads to conditions unsustainable for aquatic life. The Chesapeake Bay and Gulf of Mexico dead zones form each spring as nitrogen and phosphorus loads from farm fertilizers, atmospheric deposition and wastewater treatment plants stimulate algae blooms. These blooms eventually die and sink to the bottom, where bacteria decompose them and consume most of the oxygen. The zones dissipate each fall as changes in water currents and temperatures mix and reaerate the water—only to return the next spring.

Scavia originally developed the model to estimate the nitrogen-load reductions needed to reach particular hypoxia goals. Several years ago, he discovered that the model could also forecast the dead zone size for an upcoming season, based on the average January-May nitrogen loads for the Chesapeake Bay, and average May-June loads for the Mississippi River basin.

Source: University of Michigan

Related stories:

Fertilizers -- a growing threat to sea life
A rise in carbon emissions is not the only threat to the planet. Changes to the nitrogen cycle, caused in large part by the widespread use of fertilizers, are also damaging both water quality and aquatic life. These concerns are highlighted by Professor Grace Brush, from Johns Hopkins University in Baltimore, USA, in her historical review of landscape changes around Chesapeake Bay, a large estuary on the Atlantic coast of the USA. Her findings are published online this week in Springer's journal Estuaries and Coasts.
Scientist finds coastal dead zones may benefit some species
Coastal dead zones, an increasing concern to ecologists, the fishing industry and the public, may not be as devoid of life after all. A Brown scientist has found that dead zones do indeed support marine life, and that at least one commercially valuable clam actually benefits from oxygen-depleted waters.
Study shows continued spread of 'dead zones'
A global study led by Professor Robert Diaz of the Virginia Institute of Marine Science, College of William and Mary, shows that the number of "dead zones"—areas of seafloor with too little oxygen for most marine life—has increased by a third between 1995 and 2007.
Study shows rise in Cornwall's dolphin, whale and porpoise deaths
Four weeks on from the shocking incident that led to the death of 26 dolphins near Falmouth, research sheds new light on the extent of the problems facing Cornwall's marine mammals.
Professor says harmful byproducts of fossil fuels could be higher in urban areas
Nitrogen oxides, the noxious byproduct of burning fossil fuels that can return to Earth in rain and snow as harmful nitrate, could taint urban water supplies and roadside waterways more than scientists and regulators realize, according to research published Oct. 20 in the online edition of the journal Environmental Science and Technology.
Manganese can keep toxic hydrogen sulfide zones in check in aquatic systems
Manganese, in trace amounts, is essential to human health. Now a research team from the University of Delaware, Scripps Institution of Oceanography, the University of Hawaii and Oregon Health and Science University has discovered that a dissolved form of the mineral also is important in waterways such as the Black Sea and Chesapeake Bay, where it can keep toxic hydrogen sulfide zones in check.
'Dead Zone' kills billions of mussels
A 2001 "dead zone" that formed in Rhode Island's Narragansett Bay reportedly killed billions of mussels and destroyed at least one reef.
Ocean 'dead zones' trigger sex changes in fish, posing extinction threat
Oxygen depletion in the world’s oceans, primarily caused by agricultural run-off and pollution, could spark the development of far more male fish than female, thereby threatening some species with extinction, according to a study published today on the website of the American Chemical Society journal, Environmental Science & Technology.

News discussion:

Space & Earth science news