Huge areas of sea floor (around 3,250 km²) have been freed up by the collapse 4 years ago of the Larsen B platform along the Antarctic Peninsula – leaving a blank spot on Antarctic maps. Polarstern, the research flagship of the Alfred Wegener Institute for Polar and Marine Research, will shortly conduct there the first major biological research, studying living communities, from microbes to whales, including bottom fish and squids.
THE ITINERARYDEPARTURE - NOVEMBER 23, 2006: CAPE TOWN
The first part of the expedition will focus on biological investigations on fish stocks as a contribution to the Convention on the Conservation of Antarctic Marine Living Resources (CCAMLR, www.ccamlr.org), following a dozen similar surveys since 1976. Researchers will monitor previously fished areas located in the western part of the Antarctic Peninsula to determine the state of stock recovery.
GLOBAL WARMING & ICE SHELF COLLAPSE
When Antarctic glaciers reach the coast of the continent, they begin to float and become ice shelves, from which icebergs are then calved. Since 1974, a total of 13,500 km2 of ice shelves have disintegrated in the Antarctic Peninsula, a phenomenon linked to the regional temperature rise of more than 2°C in these past 50 years. An increasing number of scientists worry that similar break-ups in other areas could lead to increases in ice flow and cause sea level to rise dramatically. The final collapse of the Larsen B platform in February 2002 is the latest and the biggest of these catastrophic events tentatively related to global warming, freeing an additional 3,250 km2 of sea bottom of an ice cover that has been estimated to be there for at least 5,000 years.
EVOLUTION OF BOTTOM FAUNA
Meanwhile, the vanishing ice allowing vegetal and animal plankton to reinvade and thrive in these areas offers a perfect opportunity to study the evolution of bottom animal communities depending on this plankton. Sampling with various trawls, grabs and traps and the use of a remote operated vehicle with a video camera will allow the description of new species within this near-pristine environment. A dozen scientific studies will look into groups as different as microbes, sponges, crustaceans, octopuses, starfish and whales, from the grounding line to the open sea areas, and will furthermore give the best benchmark of the early stages of colonization. These studies could become a reference for other parts of Antarctica where such disintegration of ice shelves is already expected on how climate-induced shifts in biodiversity will change in ecosystems structured largely by ice.
The expedition will also lead the first biological studies of a recently discovered cold-vent ecosystem in the same Larsen area, the first of its kind known in Antarctica. Uncovered in 2005 by an American geoscience research team, this 8 km zone harbors mounds spewing out fluid and mud particles, as well as clusters of large clams. These mollusks and their associated fauna probably depend on chemical energy from the Earth, rather than one driven by photosynthesis from the sun or from hot emissions rising from inside the planet.
OUTREACH OPPORTUNITY: A MEDIA CONTACT OFFICER ONBOARD
A major anticipated expedition outcome will be extensive media coverage of research findings.
Through a media contact officer onboard, in direct contact with the AWI chief scientist and his team of researchers assisted by 2 journalists on land,
Through striking visuals obtained through state-of-the-art technology such as a remotely operated vehicle equipped with video camera and a high-resolution deep-sea still camera,
Through regular contact with global media via satellite,
A RUN UP TO THE INTERNATIONAL POLAR YEAR (IPY)
With 47 scientists onboard from more than a dozen different nationalities, the Polarstern expedition brings together an international network of research programs that will focus on the biological characteristics of this blank spot, from November 2006 to January 2007. One of the major contributors to the Census of Antarctic Marine Life (CAML), Polarstern's voyage will be a major event in the IPY, and open the way for further polar expeditions.
THE PARTNERSALFRED WEGENER INSTITUTE (AWI)
Darlene Crist | EurekAlert!
Diving robots find Antarctic winter seas exhale surprising amounts of carbon dioxide
15.08.2018 | University of Washington
Algorithm provides early warning system for tracking groundwater contamination
14.08.2018 | DOE/Lawrence Berkeley National Laboratory
Scientists at the University of California, Los Angeles present new research on a curious cosmic phenomenon known as "whistlers" -- very low frequency packets...
Scientists develop first tool to use machine learning methods to compute flow around interactively designable 3D objects. Tool will be presented at this year’s prestigious SIGGRAPH conference.
When engineers or designers want to test the aerodynamic properties of the newly designed shape of a car, airplane, or other object, they would normally model...
Researchers from TU Graz and their industry partners have unveiled a world first: the prototype of a robot-controlled, high-speed combined charging system (CCS) for electric vehicles that enables series charging of cars in various parking positions.
Global demand for electric vehicles is forecast to rise sharply: by 2025, the number of new vehicle registrations is expected to reach 25 million per year....
Proteins must be folded correctly to fulfill their molecular functions in cells. Molecular assistants called chaperones help proteins exploit their inbuilt folding potential and reach the correct three-dimensional structure. Researchers at the Max Planck Institute of Biochemistry (MPIB) have demonstrated that actin, the most abundant protein in higher developed cells, does not have the inbuilt potential to fold and instead requires special assistance to fold into its active state. The chaperone TRiC uses a previously undescribed mechanism to perform actin folding. The study was recently published in the journal Cell.
Actin is the most abundant protein in highly developed cells and has diverse functions in processes like cell stabilization, cell division and muscle...
Scientists have discovered that the electrical resistance of a copper-oxide compound depends on the magnetic field in a very unusual way -- a finding that could help direct the search for materials that can perfectly conduct electricity at room temperatur
What happens when really powerful magnets--capable of producing magnetic fields nearly two million times stronger than Earth's--are applied to materials that...
08.08.2018 | Event News
27.07.2018 | Event News
25.07.2018 | Event News
15.08.2018 | Physics and Astronomy
15.08.2018 | Earth Sciences
15.08.2018 | Physics and Astronomy