USA NOAA update in the Marine GeoGarage

13 charts have been updated in the Marine GeoGarage (NOAA update december 2010)

• 11342 : SABINE PASS AND LAKE
  
• 11384 : PENSACOLA BAY ENTRANCE
  
• 11507 : BEAUFORT RIVER TO ST SIMONS SOUND
• 11513 : ST HELENA SOUND TO SAVANNAH RIVER
• 11521 : CHARLESTON HARBOR AND APPROACHES
• 12345 : HUDSON RIVER GEO WASHINGTON BRIDGE TO YONKERS NY-NJ
• 13205 : BLOCK ISLAND SOUND AND APPROACHES
• 13214 : FISHERS ISLAND SOUND
• 13250 : WELLFLEET HARBOR MA
• 14929 : CALUMET AND INDIANA HARBORS
• 17402 : SOUTHERN ENTRANCES TO SUMNER STRAIT
  
• 18605 : TRINIDAD HARBOR
• 19482 : MIDWAY ISLANDS HAWAIIAN ISLANDS

Today 1019 NOAA raster charts (2166 including sub-charts) are included in the Marine GeoGarage viewer.

Note : correction of some problem of re-projection in Mercator (introduced for the first time in the previous update last December) for the general chart 14500 for the Great Lakes (originally in Polyconic projection)

Note : NOAA updates their nautical charts with corrections published in:

• U.S. Coast Guard Local Notices to Mariners (LNMs),
• National Geospatial-Intelligence Agency Notices to Mariners (NMs), and
• Canadian Coast Guard Notices to Mariners (CNMs)

While information provided by this Web site is intended to provide updated nautical charts, it must not be used as a substitute for the United States Coast Guard, National Geospatial-Intelligence Agency, or Canadian Coast Guard Notice to Mariner publications

Please visit the NOAA's chart update service for more info.

Deep sea BP spill dispersants din't degrade for months

A fresh oil slick from the Deepwater Horizon spill, during June 2010.
Note that one drop of detergent was added to the oil slick, forming the cleared circle.
(Photo by David L. Valentine, University of California Santa Barbara)

From ScienceNews

Nearly 3 million liters [771,000 gallons] of a chemical dispersant ejected into oil and gas from BP’s Deepwater Horizon oil spill last spring and summer lingered until at least September, a new study shows.
The chemicals moved in concert with plumes of oil deep beneath the Gulf of Mexico’s surface.

David Valentine of the University of California, Santa Barbara and his colleagues periodically sampled plume water that flowed at depths of 1,000 meters or more between May and September 2010.
They shipped these samples to chemist Elizabeth Kujawinski at the Woods Hole Oceanographic Institution in Massachusetts and her colleagues for analysis.

With rare exception, they report online Jan. 26 in Environmental Science & Technology, the dispersant did not degrade but instead moved with the plumes until they were lost to dilution in the Gulf’s depths.

Breaking up is hard to do.
When oil and gas mixtures are ejected from a deep wellhead, liquid oil droplets of many different sizes form and rise toward the ocean surface.
Because the smaller droplets become as dense as the surrounding water deep below the surface--in this case at about 1,100 meters--they are swept away laterally by prevailing ocean currents (left panel).
When a dispersant is added at the depth of the wellhead, a component called a surfactant breaks up the oil into small droplets (middle panel).
If the dispersant works perfectly, virtually all the liquid oil is in these "neutrally buoyant" droplets and is carried away before ever reaching the surface and the droplets become small enough to be consumed, or "biodegraded," by bacteria.
In the Deepwater Horizon spill (right panel), scientists found evidence that the dispersant mixed with the small droplets in the deep-water hydrocarbon plume but also discovered the oil/dispersant mix had not yet biodegraded several months after the spill.
The study could not distinguish between oil droplets coated with surfactant (which would suggest the dispersant worked as planned) and surfactant floating freely on its own (suggesting the substance did not attach to the oil, as intended).
(Credit: Jack Cook, Woods Hole Oceanographic Institution)

“If the dispersant worked, it should have been associated with the liquid oil — that is, moving off laterally into the deep-water plume. Which is where we found it — and the only place,” Kujawinski says. “We did not see it below the plume or even sloughing off the top of it.”

To scout for the dispersant, known as Corexit 9500A, Kujawinski focused on an active ingredient known as DOSS, or dioctyl sodium sulfosuccinate.
It accounted for 10 percent by weight of the dispersant mixture, which was released at rates ranging from around 13,000 to 80,000 liters [3,400 to 21,000 gallons] per day.

Prior to capping the well, plume concentrations of DOSS hovered in the low-parts-per-million range, after which it diminished to parts-per-billion concentrations.
DOSS levels in the plume matched what would have been expected if the dispersants remained with the oil.
That, Kujawinski says, suggests no biodegradation of DOSS — and shows why remnants of dispersant applications could be detected 300 kilometers [186 miles] from the wellhead and even two months after their last application.

“When you read about Corexit, it’s supposed to biodegrade,” observes Carys Mitchelmore of the University of Maryland’s Center for Environmental Science in Solomons.
But specific rates have not generally been reported, she adds. So the dispersant’s apparent persistence in the new paper is somewhat unexpected.

Then again, Mitchelmore notes, “Corexit is made up of multiple chemicals, so each might have different biodegradation rates.”
The aquatic toxicologist says she would like to see are data showing whether Corexit enhanced the ultimate breakdown of BP’s oil.

“The jury’s still out on the role of dispersants in oil degradation,” she says. “Some say they enhance it, others say they inhibit it.”

Like Mitchelmore, Beth McGee of the Chesapeake Bay Foundation in Annapolis, Maryland., served on a 2005 National Academy of Sciences assessment of oil-spill dispersants.
Clearly, McGee says, undersea use in the Deepwater Horizon spill constitutes “uncharted territory.”

“Dispersants typically degrade fairly rapidly,” McGee says.
“So the new data leave me fairly surprised.”
And, she adds, the results suggest that novel uses — such as injecting them a mile below the surface where it’s cold and there’s no light — deserve study, if only to answer questions prompted by the BP spill.

Links :

• WHOI : First study of dispersants in Gulf spill suggests a prolonged deepwater fate
• NationalGeographic : Gulf spill dispersants surprising long-lasting
• NYTimes : Study: undersea dispersant in Gulf of Mexico lingered in Deepwater plume
• Wired : No progress on better chemicals for oil disaster cleanup / EPA orders to use less-toxic oil dispersant /
  

Follow your world : Email alerts for Google imagery updates

http://followyourworld.appspot.com

From Google LatLong

Follow Your World is a notification service for Google Earth/Google Maps satellite and aerial imagery updates.
You can register a location with the service and, if that location gets fresh imagery, Google sends you an e-mail alert.
(Requires a Google account)

Useful to follow user's feedback regarding shifts of imagery position for example

(see previous article regarding Bahamas charts)

Deep ocean creatures II/II

From BBC Blue Planet

This is the most unexplored area of the planet: the deep ocean.

It begins with a whale shark used as a shield by a shoal of bait fish to protect themselves from yellowfin tuna.
Also shown is an oceanic whitetip shark trailing rainbow runners.

Down in the ocean's furthest reaches, some creatures defy the classification.
On the sea floor, scavengers such as the spider crab bide their time, awaiting carrion from above.

The volcanic mountain chain at the bottom of the Atlantic Ocean also sustains life through the bacteria that surround its sulphide vents.
There are thought to be around 30.000 undersea volcanoes, some of them taller than mount Everest.
Their sheer cliffs provide anchorage for several corals and sponges. never the surface, the currents that surround these seamounts force nutrients up from below and thus marine life around them is abundant.

Ascension Island is a nesting ground for fritebirds and green turtles.
Off the mexican coast, a large group of sailfish feed on another shoal of bait fish, changing colour to signal their intentions to each other, allowing them to coordinate their attack.

The last sequence depicts the largest animal on Earth: the blue whale, of which 300 000 once roamed the world's oceans.

Now fewer than 3% remain.....

Deep ocean creatures I/II

From BBC Blue Planet

This documentary explores the unknown depths of the ocean.
Over 60% of the sea is more than a mile deep and it forms the planet's most mysterious habitat.
A sperm whale descends 1000 metres to look for food and is followed.
On the way down, a number of unusual creatures are witnessed, such as transparent squid and jellies, whose photophores give pulsating displays of colour.
In such dark places, both being able to see (or sense movement) and the means of quick concealment are equaly desrirable.
To that end, some use bioluminescence as a means of detecting food or evading predators.
A descend to the very bottom of the ocean - some 4,000 metres - reveals life even at such cold temperatures, much of it new to science.
It is dominated by echinoderms that sweep the sea bed; however, there are occasional large hunters, such as chimaera.

Life in the Deep Oceans (part I)

The term deep sea refers to organisms that live below the photic zone of the ocean.
These creatures must survive in extremely harsh conditions, such as hundreds of atmospheres of pressure, small amounts of oxygen, very little food, no sunlight and constant extreme cold.
Most creatures have to depend on food floating down from above.
These creatures live in very harsh environments such as abyssal or hadal zones, which, being thousands of meters below the surface, are almost completely devoid of light.
The water is very cold (between 3 and 10C) and has low oxygen levels.
Due to the depth, the pressure is between 20 to 1000 atmospheres.

Barometric pressure
These animals have evolved to survive the extreme pressure of the sub-photic zones.
The pressure increases by about one atmosphere every ten meters.
To cope with the pressure, many fish are rather small, usually not exceeding 25 cm in length.
Also, scientists have discovered that the deeper these creatures live, the more gelatinous their flesh and more insignificant their skeletal structure is.

Lack of light
Because there's no light most animals have very large eyes with retinas constructed only of cones, which increases sensitivity.
Many animals have also developed large feelers to replace peripheral vision.
To be able to reproduce, many of these fish have evolved to be hermaphroditic, eliminating the need to find a mate.
Many creatures have developed very strong senses of smell to detect the chemicals released by mates.

Chemosynthesis
Since at such deep levels, there is little to no sunlight, photosynthesis is impossible as a means of energy production, leaving some creatures with the quanday of how to produce food for themselves.
For the giant tube worm, the answer comes in the form of bacteria that live inside of it.
These bacteria are capable of chemosynthesis and live inside of the giant tube worm, which lives on hydrothermal vents.
These vents spew high amounts of chemicals that these bacteria can transform into energy.
These bacteria can also grow freely of a host and create mats of bacteria on the sea floor around hydrothermal vents, where they serve as food to other creatures.
Bacteria are a key energy source in the food chain.
This source of energy creates large populations in areas around hydrothermal vents, which provides scientists an easy stop for research.

Whales can dive to about 1.200m deep in search of their prey.
The giant squid is one of the very few deep ocean creatures that can visit the ocean surface.
The viperfish have long sharp clear teeth that they use to catch their prey.
The hatchet fish has a light that attracts their prey, gulper eels have huge heads and mouths so they can swallow their prey easily.
They also have elastic stomachs, which allows them to eat fish larger than themselves. Anglerfishes use a light on top of their head to catch their prey, the rattail fish detects its prey with a whip like tail, a sea pen is like a worm like creature that lives and crawls on the ocean flood.
Many fish larger than the sea pen make it their lunch.