VIMS

Dead zones continue to spread

  • Global Hypoxia 2009
    Global Hypoxia 2009   Global pattern of coastal hypoxia in 2009. Each red dot represents a documented case related to human activities. Use scroll arrows to compare with similar data from 1989 and 1969.   Modified from Diaz and Rosenberg (2008) and updated by Rabalais et al. (2009).
  • Global Hypoxia 1989
    Global Hypoxia 1989   Global pattern of coastal hypoxia in 1989. Each red dot represents a documented case related to human activities. Use scroll arrows to compare with similar data from 2009 and 1969.   Modified from Diaz and Rosenberg (2008) and updated by Rabalais et al. (2009).
  • Global Hypoxia 1969
    Global Hypoxia 1969   Global pattern of coastal hypoxia in 1989. Each red dot represents a documented case related to human activities. Use scroll arrows to compare with similar data from 2009 and 1969.   Modified from Diaz and Rosenberg (2008) and updated by Rabalais et al. (2009).
  • Dead Zone
    Dead Zone   Scavengers feed on the remains of bottom-dwelling clams that suffocated during a hypoxic event that took place in 1976 off the New York-New Jersey coast. The oxygen-starved dead zone covered nearly 1,000 square kilometers. Photo by Dr. Don Boesch.  
  • Caspian Anoxia
    Caspian Anoxia   A cross-sectional image of the oxygen-starved seafloor beneath the Caspian Sea dead zone. Note the absence of any living creatures on or burrowed into the seafloor. Photo courtesy Joe Germano  
  • Researchers
    Researchers   VIMS Professor Bob Diaz and co-author Rutger Rosenberg of the University of Gothenburg in Sweden.  
Photo - of -
Lack of oxygen a key stressor on marine ecosystems

VIMS Professor Robert Diaz 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. Diaz and collaborator Rutger Rosenberg of the University of Gothenburg in Sweden say that dead zones are now “the key stressor on marine ecosystems” and “rank with over-fishing, habitat loss, and harmful algal blooms as global environmental problems.”

The study, which appears in the August 15 issue of the journal Science, tallies 405 dead zones in coastal waters worldwide, affecting an area of 95,000 square miles, about the size of New Zealand. The largest dead zone in the U.S., at the mouth of the Mississippi, covers more than 8,500 square miles, roughly the size of New Jersey. A dead zone also underlies much of the main-stem of Chesapeake Bay, each summer occupying about 40% of its area and up to 5% of its volume.

Diaz began studying dead zones in the mid-1980s after seeing their effect on bottom life in the Patapsco River near Baltimore. His first review of dead zones in 1995 counted 305 worldwide. That was up from his count of 162 in the 1980s, 87 in the 1970s, and 49 in the 1960s. He first found scientific reports of dead zones in the 1910s, when there were 4. Worldwide, the number of dead zones has approximately doubled each decade since the 1960s.

Diaz and Rosenberg write “There’s no other variable of such ecological importance to coastal marine ecosystems that has changed so drastically over such a short time as dissolved oxygen.”

Dead zones occur when excess nutrients, primarily nitrogen and phosphorus, enter coastal waters and help fertilize blooms of algae. When these microscopic plants die and sink to the bottom, they provide a rich food source for bacteria, which in the act of decomposition consume dissolved oxygen from surrounding waters. Major nutrient sources include fertilizers and the burning of fossil fuels.


View Larger Map

Geologic evidence shows that dead zones were not “a naturally recurring event” in Chesapeake Bay or most other estuarine ecosystems, says Diaz. “Dead zones were once rare. Now they’re commonplace. There are more of them in more places.” The first dead zone in Chesapeake Bay was reported in the 1930s.

Scientists refer to water with too little oxygen for fish and other active organisms as “hypoxic.” Diaz says that many ecosystems experience a progression in which periodic hypoxic events become seasonal and then, if nutrient inputs continue to increase, persistent. Earth’s largest dead zone, in the Baltic Sea, experiences hypoxia year-round. Chesapeake Bay experiences seasonal, summertime hypoxia through much of its main channel.

Diaz and Rosenberg note that hypoxia tends to be overlooked until it starts to affect organisms that people eat. A possible indicator of hypoxia's adverse effects on an economically important finfish species in Chesapeake Bay is the purported link between oxygen-poor bottom waters and a chronic outbreak of a bacterial disease among striped bass.

Several Bay researchers, including VIMS fish pathologist Wolfgang Vogelbein, hypothesize that the high prevalence of mycobacteriosis among Bay stripers (>75%) is due to the stress they encounter when development of the Bay's summertime dead zone forces them from the cooler bottom waters they prefer into warmer waters near the Bay surface.

Diaz and Rosenberg’s also point out a more fundamental effect of hypoxia: the loss of energy from the Bay’s food chain. By precluding or stunting the growth of bottom-dwellers such as clams and worms, hypoxia robs their predators of an important source of nutrition.

Diaz and VIMS colleague Linda Schaffner estimate that Chesapeake Bay now loses about 10,000 metric tons of carbon to hypoxia each year, 5% of the Bay’s total production of food energy. The Baltic Sea has lost 30% of its food energy—a condition that has contributed to a significant decline in its fisheries yields.

Diaz and Rosenberg say the key to reducing dead zones is “to keep fertilizers on the land and out of the sea.” Diaz says that goal is shared by farmers concerned with the high cost of buying and applying nitrogen to their crops. “They certainly don’t want to see their dollars flowing off their fields into the Bay,” says Diaz. “Scientists and farmers need to continue working together to develop farming methods that minimize the transfer of nutrients from land to sea.”

Diaz's global hypoxia study was funded in part by the National Oceanic and Atmospheric Administration.