Weekly Ocean News

WEEK NINE: 2-5 November 2009

Items of Interest:

Opportunity for Teachers: The National Ocean and Atmospheric Administration's (NOAA) Teacher at Sea 2010 Field Season program is now accepting applications until 31 December 2009. Gain your "sea legs" and first-hand experience in one week to one-month voyages. For more information, or to apply, see http://teacheratsea.noaa.gov.

Ocean in the News:

Eye on the tropics -- During the last week several tropical cyclones traveled across tropical waters of the central and western North Pacific Ocean:
- In Central North Pacific, Tropical Storm Neki weakened to a tropical depression and eventually dissipated early last week well to the northwest of the main Hawaiian Islands. Additional information on this once major category-3 hurricane (on the Saffir-Simpson Scale) can be obtained from the NASA Hurricane Page.
- In western North Pacific basin, Typhoon Mirinae formed at the start of last week east of Guam in the Marianas and traveled westward becoming a category-2 typhoon (on the Saffir-Simpson Scale) by late week when it made landfall along the Philippine Islands. This typhoon quickly weakened to a tropical storm as it moved across the Philippines and then across the South China Sea. As of early Monday Tropical Storm Mirinae was approaching the central coast of Viet Nam. Additional information along with satellite images on Typhoon Mirinae can be found on the NASA Hurricane Page.
Nearshore habitat management gets a boost along Chesapeake and Delaware Bays -- The Smithsonian Institution’s Environmental Research Center and several partner organizations will be getting funding from the NOAA National Centers for Coastal Ocean Science’s Center for Sponsored Coastal Ocean Research for a five-year collaborative project designed to study the degradation of the nearshore coastal habitats in Chesapeake and Delaware Bays, as well as to assist environmental managers restore and protect these estuaries. [NOAA News]
An award given to improve management of Gulf's "dead zone" -- NOAA's Northern Gulf of Mexico Ecosystems and Hypoxia Assessment Program had awarded funding for a multi-year project designed to support coastal science research on the hypoxic "dead zone" in the northern Gulf of Mexico as part of the interagency Mississippi River/Gulf of Mexico Watershed Nutrient Task Force’s Action Plan. [NOAA News]
Coral reef threats to be studied -- NOAA and The Nature Conservancy have signed a four-year agreement involving matching funds designated to address three major threats facing the nation's vulnerable coral reef ecosystems in the Caribbean, Florida, Hawaii and the Pacific Islands. The three threats facing coral reef ecosystems involve: climate change, overfishing, and land-based sources of pollution. [NOAA News]
South Atlantic alliance partners announced -- Officials from NOAA and four Southeastern States recently announced the formation of the Governors’ South Atlantic Alliance that will better manage and protect ocean and coastal resources, ensure regional economic sustainability, and respond to natural disasters such as hurricanes. [NOAA News]
Seafood inspection to get combined resources -- NOAA’s Fisheries Service Seafood Inspection Program and the U.S. Food and Drug Administration recently unveiled an interagency agreement today to strengthen seafood inspection and improve seafood safety and quality. [NOAA News]
New technology used to tag turtles for study -- Researchers at NOAA’s Northeast Fisheries Science Center have been using a remotely operated submersible vehicle and satellite-linked data loggers to track loggerhead turtles to learn more about the turtles' behavior and how they interact within their marine habitat. [NOAA Northeast Fisheries Science Center]
An oil slick seen from space -- An image obtained last week from the MODIS sensor on NASA's Aqua satellite shows a large oil slick on the waters of the Timor Sea between northwest Australia and Indonesia caused by a blowout of an oil well several months ago. [NASA Earth Observatory]
Satellite captures algal bloom off New Zealand -- Early last week, a MODIS sensor on NASA's Aqua satellite captured an image of springtime algal bloom in the surface waters off the eastern coast of New Zealand. This bloom was found in several swirls marking the meeting of several water streams of warm water flowing southward and cold water coming from off the Antarctic Circumpolar Current [NASA Earth Observatory]
Deep dives taken by new UK equipment -- Engineers from the United Kingdom's National Oceanography Centre, Southampton recently tested some new equipment in waters of the North Atlantic off the Iberian Peninsula and Morocco last month during an engineering trials cruise on the RRS Discovery. They guided Autosub6000, the United Kingdom's deepest diving Autonomous Underwater Vehicle, on several dives to depths of approximately 3.5 miles below the surface of the North Atlantic. [EurekAlert!] They also tested the hydraulic benthic interactive sampler HyBIS, exploring the Casablanca seamount at depths of 2.8 miles off Morocco. [EurekAlert!]
New European Earth observation satellite readied for launch -- The European Space Agency (ESA) Soil Moisture & Ocean Salinity (SMOS) satellite, a new European Earth observation satellite, is scheduled to be launched early Monday from northern Russia. This satellite is to measure both soil moisture levels and the salinity of the surface waters of the world's oceans. [Natural Environment Research Council] The launch can be followed on line on the ESA website. [ESA]
Global shellfish decline possibly linked to ocean acidification -- Researchers at Stony Brook University have found that increased levels of carbon dioxide dissolved in seawater and the associated increases in ocean acidification appear to have detrimental effects upon the growth and survival of a variety of shellfish species including hard clams, bay scallops and Eastern oysters. [EurekAlert!]
Rapid rise in sea level seen along the Carolina coast -- A team of environmental scientists from the University of Pennsylvania, East Carolina University, Florida International University, the Netherlands' Vrije Universiteit, England's University of Plymouth and Ireland's University College Dublin studying North Carolina salt marshes has found that during the 20th century sea level along the coast of the Carolinas appears to have risen at a rate three times higher than the rate of sea-level rise during the last 500 years. They conclude that the jump in sea level between 1879 and 1915 appears to be related directly to human-induced climate change. [EurekAlert!]
Israel could be hit by tsunami waves -- New archaeological research conducted at the University of Haifa has provided evidence that the coast of Israel has experienced four tsunami events that developed in the Mediterranean at about 1500 BC, 100-200 CE, 500-600 CE, and 1100-1200 CE. [EurekAlert!]
Studying ancient ocean chemistry to determine early increases in free oxygen -- Analysis of 2.5 billion-year-old black shales from Western Australia has led geoscientists at the University of California, Riverside, Arizona State University and the United Kingdom's University of Leeds to conclude that oxygen production began in Earth's oceans at least 100 million years before the "Great Oxidation Event" a time approximately 2.4 billion years ago when oxygen levels rose sharply in the Earth's atmosphere. [EurekAlert!]
Ancient volcanoes helped end an early ice age -- Researchers at Ohio State and Penn State Universities have discovered that massive amounts of carbon dioxide released into the atmosphere by giant volcanoes approximately 450 million years ago appear to have helped cause sufficient global warming so as to end a deadly ice age, which had killed nearly two-thirds of all species existing on the planet. These giant volcanoes occurred during the closing of the Iapetus Ocean, the proto-Atlantic Ocean, during the Paleozoic era when the rise of the Appalachian Mountains was removing carbon dioxide and helping maintain the ice age through global cooling. [Ohio State University]
An All-Hazards Monitor -- This Web portal provides the user information from NOAA on current environmental events that may pose as hazards such as tropical weather, marine weather, tsunamis, rip currents, Harmful Algal Blooms (HABs) and coral bleaching. [NOAAWatch]
Global and US Hazards/Climate Extremes -- A review and analysis of the global impacts of various weather-related events, including drought, floods, and storms during the current month. [NCDC]
Earthweek -- Diary of the Planet [earthweek.com] Requires Adobe Acrobat Reader.

Concept of the Week: Controlling Nutrient Input into Chesapeake Bay

Chesapeake Bay is the nation's largest estuary; it is more than 300 km (185 mi) long, 65 km (40 mi) at its broadest, and averages about 20 m (66 ft) deep. The estuary was formed by the post-glacial rise in sea level that flooded the valley of the ancient Susquehanna River. The Bay receives about half its water from the Atlantic Ocean and the other half from the more than 150 rivers and streams draining a 166,000 square kilometer land area encompassing parts of New York, Pennsylvania, West Virginia, Delaware, Maryland, Virginia, and the District of Columbia. Major rivers that empty into Chesapeake Bay include the Potomac, Susquehanna, York, and James.

As described in more detail on pages 183-185 of your DataStreme Ocean textbook, an estuary is a complex and highly productive ecosystem where seawater and freshwater runoff meet and mix to some degree. In Chesapeake Bay, more-dense seawater creeps northward along the bottom of the estuary, moving under the less-dense fresh water flowing in the opposite direction. This circulation combined with wind-driven and tidal water motions causes salinity to decrease upstream in the Bay, from values typical of the open ocean at its mouth to freshwater values at its northern margin.

As in all ecosystems, organisms living in estuaries depend on one another and their physical environment for food energy and habitat. Phytoplankton and submerged aquatic vegetation (e.g., marsh grass) are the primary producers (autotrophs) in estuarine food chains. Chesapeake Bay consumers (heterotrophs) include zooplankton, finfish, shellfish, birds, and humans.

Human activity has greatly modified Chesapeake Bay with consequences for the functioning of the ecosystem. Much of the original forests that covered its drainage basin were cleared and converted to farmland, roads, cities, and suburban developments. These modifications accelerated the influx of nutrients (i.e., compounds of phosphorus and nitrogen), sediment, pesticides, and other pollutants into the Bay. More nutrients spur growth of algal populations and when these organisms die (in mid-summer), their remains sink to the bottom. Decomposition of their remains reduces dissolved oxygen levels in the Chesapeake's bottom water. More sediment increases the turbidity of the water, reducing sunlight penetration for photosynthesis. Presently Chesapeake Bay is on the Federal list of "impaired waters" and in need of pollution abatement and remediation. States in the drainage basin have agreed to work together to clean up the Bay but there are significant obstacles including cost.

One casualty of human modification of the Chesapeake Bay ecosystem was marsh grass-reduced by 90% from historical levels. Marsh grass anchors sediment and dampens wave action thereby controlling shoreline erosion and turbidity. Marsh grass is a food source for many organisms including waterfowl and small mammals and serves as a primary nursery for crabs and many species of fish. Reduction of this habitat along with over-fishing has been implicated in the decline of populations of blue crabs, a mainstay of the Bay fishery for more than a century. Over the past decade, the number of adult female blue crabs plunged by 80%. Without adequate protection by marsh grass, blue crabs are more vulnerable to predation by striped bass (i.e., rockfish). Striped bass turned to blue crabs as a food source when fishing reduced the numbers of menhaden, their preferred food. Menhaden is a marine fish in the herring family and the Bay's top fishery by weight.

Human modification of the Chesapeake Bay drainage basin converted it from an essentially closed system to an open system. In the original climax forests, nutrients primarily cycled within the system with relatively little input to the Bay. Modification of the land for agriculture increased the area of the soil exposed to the elements and runoff from rain and snowmelt accelerated nutrient input into the Bay. In addition to such non-point (area) sources of nutrients are point sources including the effluent of wastewater treatment plants that discharge treated water into rivers and streams that drain into the Bay.

For decades, agriculture has successfully employed various cultivation practices that limit the runoff from cropland (e.g., contour plowing, strip cropping, and retention ponds.) However, less than one-third of the 300-wastewater treatment facilities located in the Chesapeake Bay drainage basin have the technology to remove high levels of nutrients from their effluent. Under current environmental regulations, states are not required to regulate the nutrient content of this discharge. But in late October 2003, the Chesapeake Bay Foundation, a private, not-for-profit environmental advocacy organization called on Virginia, Maryland, Pennsylvania, and the District of Columbia to specify nutrient limits on permits they grant to all wastewater treatment facilities. In support of their recommendations, the Chesapeake Bay Foundation cited the many water quality problems stemming from excessive nutrient load in the Bay waters (e.g., algal blooms, spread of "dead zones.") According to the U. S. EPA, under the federal Clean Water Act, a state can control nitrogen pollution if it determines that environmental harm is taking place. However, the EPA estimates that as much as $4.4 billion would be required to install state-of-the-art nutrient removal technologies at all major plants (those treating more than 500,000 gallons of wastewater per day).

Concept of the Week: Questions

In terms of nutrient cycling, the climax forest that originally occupied the Chesapeake Bay drainage basin was a(n) [(open)(closed)] system.
Excessive input of nutrients into Chesapeake Bay [(spurs the growth of)(has little impact on)] algal populations and [(increases)(reduces)] the concentration of dissolved oxygen in bottom waters.

Historical Events:

2 November 1493...Explorer Christopher Columbus first sighted the island of Dominica in the Caribbean Sea.
3 November 1975...The North Sea pipeline, Firth of Forth, was opened by Queen Elizabeth II. The first oil was piped ashore from the North Sea at Peterhead, Scotland in a pipe that ran from British Petroleum's "Forties Field" for 110 miles along the seabed and then 130 miles to the oil refinery at Grangemouth. The field was discovered by the drilling rig Sea Quest in October 1970. (Today in Science History)
6 November 1528...Shipwrecked Spanish conquistador Álvar Núñez Cabeza de Vaca became the first known European to set foot on Texas soil, near present-day Galveston Island. (Wikipedia)