AW: Polare Umwelten

AW: Polare Umwelten


Im Osten der Antarktis und östlich des Unzugänglichkeitspols findet sich unter einer 600m starken Eisdecke ein Gebirge, so gross wie die Alpen und bis zu einer Höhe von 3'400m aufsteigend. Von der 3. Sowjetischen Antarktis-Expedition 1958 entdeckt, wurde es nach dem drei Jahre zuvor verstorbenen russischen Seismologen Grigoriy A. Gamburtsev benannt.

Gebirgsbildung erklärt das Lehrbuch aus der Plattentektonik. Der Druck zweier Platten wird in Form von Masse nach oben abgeleitet. Schon steht ein Gebirge da. Im Falle des Gamburtsevs fehlen solche Platten. Das Gebirge ist trotzdem da. Warum?

Das versucht ein Leitprojekt des Internationalen Polarjahrs herauszufinden. Die Forschungsprojekte heissen "AGAP: Antarctica's Gamburtsev Province" und "GIGAGAP: Geoscientific Insights of Greater Antarctica in the area from Gamburtsev Mountains, Amery Ice Shelf to Prydz Bay".


Auf der deutschen Polarjahrseite findet sich nichts zu dem Projekt, obwohl es mit Detlef Damaske von der Bundesanstalt für Geowissenschaften und Rohstoffe in Hannover unter deutscher Ko-Leitung (zusammen mit Chris Wilson von der Universität Melbourne) steht.

Auf der internationalen Polarjahrseite heisst das Projekt Origin, evolution and setting of the Gamburtsev subglacial highlands: Exploring an unknown territory.

Weitere Auskünfte geben die Projektvorschläge 558 und 934.

Die frischeste Information scheint es auf der Seite der Bundesanstalt für Geowissenschaften und Rohstoffe zu geben:

Zwei Presseberichte:

Jonathan Amos, Survey targets 'ghost' mountains [BBC News, December 13, 2006]

Julia Stuart, The cold, hard facts behind Antarctica's frozen peaks [Independent, May 23, 2007]

Bonus: Grönlandwal mit 211 Jahren von Walfängern getötet [Welt, 25. Mai 2007]

AW: Polare Umwelten



Zum Weltumwelttag am 5. Juni 2007 wartet die Umweltorganisation der Vereinten Nationen mit zwei gewichtigen Studien auf:



Ich erinnere daran, dass der Weltentwicklungsbericht 2006 sich mit dem flüssigen Aggregatzustand des Wassers, nämlich Globalen Wasserkrisen, befasst.

AW: Polare Umwelten

AW: Polare Umwelten

AW: Polare Umwelten




Integrated Global Observing Strategy (IGOS) ist eine Partnerschaft internationaler Organisationen, die Regelwerke für den Umgang mit den Datenmassen der Erdbeobachtung erarbeitet. Insbesondere die Integration satelliten-, flugzeug- und bodenerhobener Daten liegt IGOS am Herzen. Am 29. Mai 2007 hat die Organisation das Regelwerk für die Cryosphäre, den Cryosphere Report (das griechische kryos steht für Frost), also eine Gesamtdatenstrategie für das Globale Eis, veröffentlicht. Wir hatten bereits in Beitrag #18 Globaleis & Polartourismus auf den Welteisbericht der Umweltorganisation der Vereinten Nationen Global Outlook for Ice & Snow hingewiesen, der das Weltwissen über das Welteis zusammenfasst.

AW: Polare Umwelten




Das Internationale Polarjahr 2007-2008, das von März 2007 bis März 2009, also zwei volle Jahre, dauert, ist eine einzigartige Gelegenheit, sich mit der globalen Polarforschung vertraut zu machen.

Organisiert wird es vom International Council for Science, dem Weltdachverband von 111 nationalen Forschungsförderungsorganisationen und 29 internationalen Forschungsverbänden, und der World Meteorological Organization, der Sonderorganisation der Vereinten Nationen für Meteorologie, Hydrologie und Geophysik.

Nach 1882-1883, 1932-1933 und 1957-1958 ist es das vierte Mal, dass die internationale Wissenschaftsgemeinschaft die Polarforschung umfassend unterstützt.

Es steht ein Budget von $ 1,5 Mrd zur Verfügung, aus dem, mit Stand Februar 2007, 228 Projekte finanziert werden. 171 Projekte dienen der Forschung, 57 erfüllen Bildungsaufgaben. Alles in allem werden 50'000 Personen am Internationalen Polarjahr mitwirken.

Sinn eines solchen Grossforschungsunternehmens sind Schaffung und Ausbau langfristig nutzbarer Forschungsinfrastrukturen, Zusammenführung von Forschungsansätzen, Etablierung neuer Forschungsmethoden, Selbstreflexion der beteiligten Wissenschaften und Wissenschaftskommunikation nach aussen.

Bei den genannten Dimensionen ist es nicht leicht, einen Überblick zu gewinnen. Deshalb erfolgt hier eine Hilfestellung.


Als erstes sollte man die achtzigseitige Broschüre The Scope of Science for the International Polar Year 2007–2008, Paris: ICSU/WMO Joint Committee 2007, herunterladen.

Der Einstieg erfolgt über den Chart auf Seite 14. Im Adobe Reader Menu kann man unter "Anzeige" die "Ansicht drehen".


Der Chart zeigt alle 228 Projekte in Rauten mit Kurztitel und Projektnummer. Die Projektnummer brauchen wir, um zu den Projektseiten im Internet zu gelangen.

Angeordnet werden die Projekte in drei Schichten und acht Spalten. Projekte zur Arktis finden sich in der obersten Schicht, bipolare Projekte in der mittleren, und unten finden sich die Projekte zur Antarktis.

Die Spalten führen vom Erdinnern zum Weltraum: Geologie, Boden, Bevölkerung, Ozean, Eis, Atmosphäre, Weltraum.

Innerhalb dieser Koordinaten sind die Projekte nach Ähnlichkeit gruppiert.

Der Chart ist wirklich eine grosse Hilfe. Den Rauten fehlen, leider, nur die Links zu den Projekten.

Wenn man einen Bildbetrachter wie Irfan hat, sollte man sich ein .jpg des Charts erstellen. Mit der Taste "Druck" rechts oben auf der Tastatur befördern wir die Bildschirmansicht in die Zwischenablage. Mit "Einfügen" und "Bearbeiten" öffnen wir diese in Irfan. Jetzt können wir mit der linken Maustaste den Umriss des Charts markieren. In Irfan wählen wir dann unter "Bearbeiten" das Feld "Freistellen". Jetzt können wir, nach einer fakultativen Bildgrössenänderung, den Chart als .jpg abspeichern.

Auf Seite 71 bis 78 der Broschüre steht eine Liste der 228 bewilligten Projekte. Nach der Projektnummer folgt der vollständige Projekttitel.

Der Text der gut geschriebenen Broschüre führt in allgemein verständlicher Form in die Themenstellungen des Internationalen Polarjahrs ein. Eine bessere Einführung wird man nirgends bekommen.

Neben der offiziellen internationalen Webseite gibt es nationale Webseiten der beteiligten Länder.

Die vom Alfred-Wegener-Institut für Polar- und Meeresforschung betreute deutsche Polarjahr-Seite erfreut allerdings nur beim ersten Anblick.

Versprochen wird ein Überblick über die deutschen Beteiligungen. Es werden jedoch längst nicht alle aufgeführt. Unter den gelisteten Projekten finden sich solche, die nicht bewilligt oder in anderen Projekten aufgegangen sind. Die Übersetzungen aus dem Englischen sind oft hanebüchen. Das ganze macht den Eindruck eine HiWi-Arbeit, die in der Vertragszeit unvollendet blieb.

Wenden wir uns der offiziellen Webseite zu. Sie bevorzugt, milde ausgedrückt, einen "no frill"-Ansatz des Webdesigns. Hat man die Architektur der Seite verstanden, kann man, ohne auf viele Fehler zu stossen, mit der Seite arbeiten.

Wir wählen oben auf der Seite im Feld "Browse by Content Type" das Feld "Projects". Nach Laden der Seite geben wir bei "Items per page" die Zahl 40 ein.

Damit hat man die Projektliste mit Links zu den Projektseiten vor sich. Ich rate allerdings davon ab, Projekt für Projekt anzusehen. Der Nicht-Fachmann bräuchte Tage, um sich zurechtzufinden.

Besser ist es, den Chart zu nutzen und sich die Projektnummern interessierender Projekte zu notieren.

Hat man die 40er-Einstellung wie beschrieben gewählt, dann finden sich auf Seite Eins die Projektnummern 460-384, auf Seite Zwei 379-262, auf Drei 259-162, auf Vier 160-104, auf Fünf 100-42 und auf Sechs 41-6.

Auf der Projektseite steht, manchmal, eine brauchbare Zusammenfassung. Weiter geht es mit "Link to proposal", manchmal, so schon vorhanden, mit "Link to website" zur Homepage des Projekts.

"Link to proposal" öffnet mit dem Antragstext die unleidlichste Textsorte des akademischen Betriebs, die Antragsprosa. Wer tapfer ist, kann der Seite trotzdem eine Fülle von Informationen entnehmen und, z.B. über die Personennamen, im Netz weiter recherchieren.

Ist der Einstieg ins Polarjahr auch etwas mühsam, so darf man, sind die Grundlagen gelegt, mit einer üppigen Online-Ernte rechnen. Sämtliche Projekte sollen, nach dem Willen der Veranstalter, ihre Forschungen auf eigenen Webseiten und online zugänglichen Datenbanken präsentieren. Schliesslich sind es Steuerzahler weltweit, die das Internationale Polarjahr finanzieren.

Es folgt, mit getrennter Post, meine derzeit 49 Projekte umfassende Auswahl. Auf zwei Projekte sind wir in den Beiträgen Biodiversität der antarktischen Tiefsee (Projekt 66, Beitrag #13) und Das antarktische subglaziale Gamburtsev Gebirge (Projekt 67, Beitrag #17) bereits eingegangen.

AW: Polare Umwelten




{11} Arctic Wildlife Observatories Linking Vulnerable EcoSystems

Gilles Gauthier, Centre d’études nordiques, Université Laval, Canada

Our project will focus on key species of herbivores (e.g. geese, lemmings, and muskox), insectivores (e.g. shorebirds), and predators (e.g. foxes, snowy owls, falcons, gulls, and jaegers), and their interactions at a large number of arctic sites across North America and Eurasia.


{90} Arctic Circum-Polar Coastal Observatory Network [de]

Paul Overduin, Alfred Wegener Institute for Polar and Marine Research, Germany

The coastal zone is the interface through which land-ocean exchanges in the Arctic are mediated and it is the region of most high-latitude human activities. | A coordinated monitoring programme incorporating diverse regions and providing site-specific, fine-scale baseline and time-series data will yield maximum value, facilitating local and circum-Arctic studies, such as validation of multiscale biodiversity and coastal community models.


{72} Network for Arctic Climate and Biological Diversity Studies [ArcDiv Net]

Jon Børre Ørbæk, Norwegian Polar Institute, Norway

The Network for Arctic Climate and Biological Diversity Studies (ARCDIV) is a multidisciplinary research cluster under the International Polar Year (IPY 2007-2008), seeking to explore the diversity of climates and ecosystems at landscape scale within the Arctic region, by integrating historical, existing and new intense measurements of key physical and biological variables and processes at multiple Arctic observational sites.


{448} People, wilderness and tourism

Tomas Willebrand, Swedish University of Agricultural Sciences, Sweden

This proposal aim to investigate and contrast data on the efforts and levels of rural residents in harvesting wild berries, freshwater fish and wildlife in the arctic region. We will evaluate the potential for nature tourism development and potential pressure on these activities caused by the climate change.


{46} Monitoring Oil Development [pdf]

Winfried Dallmann, Norwegian Polar Institute, Norway

Intensive oil-and-gas development occurs under Arctic conditions in the Nenets Autonomous Okrug (NAO). Severe impacts occur, both on the environment and on the socio-economic situation of the indigenous peoples living in and of the land. The project aims at monitoring the situation and producing a GIS database, which documents activities and can be used to promote interests of traditional land users.


{435} Heritage in Ice

Sheila Greer, Champagne and Aishihik First Nations, Canada

This activity involves science and social science research that has been initiated as a result of the recent melting of glaciers and alpine ice patches. Melting of these scientific “deep freezes”, is providing unanticipated data sources that are giving us insight into past northern societies, flora/fauna, environments, and their changes through time.


{48} International Study of Arctic Change

Leif Anderson, Department of Chemistry Goteborg University, Sweden

The International Study of Arctic Change, or ISAC, is a long-term, interdisciplinary program to study the causes and effects of environmental changes (including physical/chemical, biological/ecological, and socioeconomic/cultural changes) on the pan – Arctic scale with emphasis on the linkage to global dynamics.


{333} ArcOD: Arctic Ocean Diversity [Arctic Ocean Biodiversity]

Rolf Gradinger, University of Alaska Fairbanks, USA

ArcOD is an international collaborative effort to inventory biodiversity in the Arctic’s three realms (sea ice, water column and sea floor) from the shallow shelves to the deep basins using a three-step approach: compilation of existing data, taxonomic identification of existing samples, and new collections focusing on taxonomic, regional and other gaps from land based stations, and ice breaker expeditions.


{22} POLARSTERN Expedition HERMES: The Nordic Margin [HERMES] [de]

Michael Klages, Alfred Wegener Institute for Polar and Marine Research, Germany

We propose a POLARSTERN research expedition covering several types of Arctic margin habitats. The project HERMES is designed to gain new insights into the biodiversity, structure, function and dynamics of ecosystems along Europe’s deep-ocean margin to underpin the future development of a comprehensive European Ocean and Seas Integrated Governance Policy.


{305} Consortium for Coordination of Observation and Monitoring of the Arctic for Assessment and Research

Terry Callaghan, Royal Swedish Academy of Sciences, Abisko Scientific Research Station, Sweden

COMAAR will be established as a consortium under the auspices of the Arctic Council, composed of AC Working Groups, major observation and monitoring networks, platforms/observatories, government agencies and other relevant institutions involved in observation and monitoring in the Arctic. The main objectives of COMAAR are to increase effectiveness and efficiency in the use of infrastructure, personnel and funding, and to improve coordination for sustained long-term time series observations and for data handling.


{40} DAMOCLES: Developing Arctic Modelling and Observing Capabilities for Long-term Environmental Studies [DAMOCLES] [de]

Jean-Claude Gascard, Université Pierre et Marie Curie, France

The main objective of DAMOCLES is to reduce the uncertainties in our understanding of climate change in the Arctic and in the impacts thereof. To meet this objective DAMOCLES will, following the approach of Numerical Weather Prediction Centers, develop an integrated system for obtaining relevant geophysical observations, transferring them to a central databank, distributing them to the modelling centers, and producing nowcasts and forecasts of the Arctic climate.


{14} IAOOS: Integrated Arctic Ocean Observing System [pdf]

Leif Anderson, Department of Chemistry Goteborg University, Sweden

A Global Climate Observing System was set up by the United Nations in 1992, but major gaps exist at high latitudes because the harsh environmental conditions make gathering this data very difficult. iAOOS – a project involving a dozen countries, including the UK, USA, Russia and China – will help plug this gap by setting up a long-term ocean monitoring system in the Arctic.


{37} GLACIODYN [GLACIODYN]

Johannes Oerlemans, IMAU, Utrecht University, Netherlands

Global Warming will have a large impact on glaciers in the Arctic region. Sea level will be affected, and substantial changes can be expected in sediment and fresh water supplies to embayments and fjords. In GLACIODYN we study the dynamics of Arctic glaciers by means of field observations, remote sensing from satellites, and computer modelling. This will deliver tools to make more accurate predictions about future changes.


{120} NORCLIM: Northern High Latitude Climate variability during the past 2000 years

Simon Troelstra, Vrije Universiteit Amsterdam, Netherlands

NORCLIM investigates how natural climate change over the past two millenia has affected human presence in the Arctic. Examples are the timing of Viking settlement on the Faroer, Iceland, Greenland and Newfoundland and the shift in whaling activities from Spitsbergen to Davis Strait during the Little Ice Age.


{36} Arctic Ocean Warming in the Past

Morten Hald, Department of Geology, University of Tromsoe, Norway

The overall goal of this initiative is to advance our knowledge of climate warming in the Arctic, by studying past climate change. We will focus mainly on the ocean circulation and climate of the NW Eurasian continental margin.


{118} The Greenland Ice Sheet: Stability, History and Evolution

Dorthe Dahl-Jensen, University of Copenhagen, Denmark

The Greenland Ice Sheet is an outstanding archive of information about what the Earth’s climate was like in the past, and the water locked in its ice will have a major impact on sea level rise due to climate change. Because of this, understanding how Greenland will react to global warming is crucially important. By gathering seismic data, ice cores and using radar, laser ranging and echo sounders, this project will shed new light on the Greenland Ice Sheet and improve scientists’ ability to model how it will react to climate change.


{266} Remote sensing, monitoring, and forecast of surging glaciers’ evolution

Vladimir Kotlyakov, Institute of Geography, Russian Academy of Sciences, Russia

At present as a result of field investigations, air photos and space images the regularities of fluctuations of many surging glaciers of the Pamirs (Oktyabrskiy, Gando, Bivachniy, Sugran and others) are investigated in detail. The Inventory of Surging Glaciers of the Pamirs was compiled. The experience of monitoring of these glaciers may be distributed at the glaciers of polar regions. That’s why it is proposed to fulfil remote sensing investigations of surging glaciers of Alaska, Svalbard and Pamirs on the base of space images.


{39} APEX: Arctic Palaeoclimate and its Extremes [APEX]

Martin Jakobsson, Stockholm University, Dept. of Geology and Geochemistry, Sweden

Our particular emphasis is to focus on the magnitude/frequency of the climate variability and, in particular, the "extremes" versus the “normal” conditions of the climate system. It is an interdisciplinary programme that integrates marine and terrestrial science and utilises modelling and field observations.


{38} OASIS-IPY: Ocean-Atmosphere-Sea Ice Snowpack Interactions and Connections to Climate Change [OASIS]

Harry Beine, C.N.R. - IIA, Monterotondo Scalo (Roma), Italy

OASIS will make use of a variety of platforms (icebreakers, ice islands, buoys) to obtain year-round information on the behavior of such key chemicals as ozone, mercury, and carbon dioxide. As the nature and extent of snow and ice cover is changing OASIS will assess the associated impact on, and by, climate change, and the human and ecosystem impacts of these chemicals.


{357} SCSCS: Spitsbergen Climate System Current Status

Sergey Pryamikov, Arctic and Antarctic Research Institute of Roshydromet, Russia

Thus, Cryosphere, Hydrosphere, atmosphere and biosphere of the Archipelago is a noticeable objects-indicator of the current status of the Arctic climate system and estimates of its future changes.


{28} IPY-CARE: Climate of the Arctic and its role for Europe/Arctic System Reanalysis [IPY-CARE]

Ola M Johannessen, Nansen Environmental and Remote Sensing Center, Norway

The overall objective of CARE/ASR is to explore, quantify and model Arctic climate change, its interaction with the climate in lower latitudes and its impact on Arctic marine ecosystems, and to assess the socio-economic consequences for Europe.


{196} International Arctic Systems for Observing the Atmosphere [IASOA]

Taneil Uttal, U.S. National Oceanic and Atmospheric Administration, United States

The Arctic Skies Program is coordinating intensive measurements of the Arctic Atmosphere in Canada, Russia, Norway, Finland, Sweden and the U.S. The focus of the program is to combine information so that it can be determined WHY and not just HOW the atmosphere is affecting Arctic climate change.

AW: Polare Umwelten




{77} PLATES & GATES: Plate tectonics and polar ocean gateways [PLATES & GATES] [de]

Karsten Gohl, Alfred Wegener Institute for Polar and Marine Research, Germany

Establishing the detailed tectonic, geodynamic, sedimentary and paleo-topographic histories of strategic oceanic basins and gateways will provide the essential framework for modelling studies that will relate these events to paleo-climate observations collected across the globe.


{185} POLENET: Polar Earth Observing Network [POLENET]

Terry Wilson, Ohio State University, USA

POLENET will deploy an ambitious array of geophysical instruments across the polar regions in order to study the complex interplay between climate, ice sheets, geodynamics, and global sea level change. | Scientists, engineers, field assistants and students are deploying new GPS instruments, seismic stations, magnetometers, tide gauges, ocean-floor sensors and meteorological recorders. They are launching satellites, travelling to remote locations and combining their expertise across a vast range of data analysis techniques.


{50} Permafrost Observatory: Project-Thermal State of Permafrost

Jerry Brown, International Permafrost Association, Norway/US

International Permafrost Association, as its contribution to the International Polar Year, will obtain a ”snapshot” of the polar environments as a benchmark against which to assess past and future changes. Toward this end, IPA is mobilizing the international permafrost community to make standardized temperature measurements in existing and new boreholes throughout the permafrost regions of both hemispheres including the mountainous regions and plateaus of the mid- and low-latitudes.


{132} CASO: Climate of Antarctica and the Southern Ocean [CASO] [de]

Stephen Rintoul, ACE CRC and CSIRO Marine and Atmospheric Research, Australia

CASO aims to enhance understanding of the role of the Southern Ocean in past, present and future climate, including the overturning circulation of the Southern Ocean, water mass transformation, atmospheric variability, ocean-cryosphere interactions, physical-biogeochemical-ecological linkages, and teleconnections between polar and lower latitudes.


{130} BIPOMAC: Bipolar Climate Machinery [de]

Rainer Gersonde, Alfred Wegener Institute for Polar and Marine Research, Germany

The BIPOMAC project will collect and examine climate records in sedimentary sequences spanning the past five million years from both polar regions. These records will provide a basis for analysing the complex interactions of environmental processes that have caused the observed patterns of climate variation.


{367} NICE STREAMS:Neogene Ice Streams and Sedimentary Processes on High Latitude Continental Margins

Angelo Camerlenghi, University of Barcelona, Spain

During glacial periods ice sheets move faster along so called ‘ice streams’. Ice streams leave footprints on the seafloor when the ice is grounded below the sealevel. This project aims at developing new models of fast ice flow in ice-streams based on analyses of the geological record of past ice-streams.


{105} The State and Fate of the Cryosphere

Jeffrey Key, CLiC, USA

This project will provide a framework for assessing the state of cryosphere. It will establish links with IPY projects involved in monitoring, assessing, and understanding the global cryosphere, and with projects involved in socioeconomic and cultural issues.


{117} IPICS-IPY: International Partnerships in Ice Core Science [IPICS]

Edward Brook, Oregon State University, USA

Ice cores tell us how climate and atmospheric composition have varied in the past. IPICS will develop international plans for new projects on timescales from 2000 to over a million years. A focus in IPY will be on starting a core to bedrock in Greenland that aims to show us how the climate and ice sheet responded during the last warm interglacial period on Earth.


{121} THORPEX-IPY: Improved numerical weather forecasting and climate simulations

Thor Erik Nordeng, Norwegian Meteorological Institute, Norway

Using satellite data, this 15-nation project will help design the next generation of observing networks that are needed to improve our ability to forecast “high impact” weather events in polar regions.


{91} GIIPSY: Global Interagency IPY Polar Snapshot Year [GIIPSY]

Mark Drinkwater, European Space Agency, ESTEC, Netherlands/ Ken Jezek, The Ohio State University, USA

Because competition for access to satellite resources is intense, GIIPSY will coordinate polar observations with spaceborne and in-situ instruments and make the resulting data set – a snapshot of the polar ice sheets at the start of the 21st century – available to the international science community.


{372} Polar View: The Polar Information Centre [Polar View]

Charles Randell, C-CORE, Canada

Polar View brings together - for the first time - multiple satellite observations to provide timely data for polar monitoring. Via an international consortium funded by the European Space Agency, Polar View will deliver accurate, near-real-time information about sea ice conditions in the Arctic and Antarctic, data that other IPY projects working on ships in sea ice will be able to use to improve the efficiency of their operations.

AW: Polare Umwelten




{67} Origin, evolution and setting of the Gamburtsev subglacial highlands: Exploring an unknown Antarctic territory

Detlef Damaske, BGR, Germany

Discovered during International Geophysical Year 1957-1958, Antarctica’s Gamburtsev Mountains extend for more than 1,200 km and rise to heights of over 3,000 m. These mountains, however, have never been seen by humans because they are covered by ice up to 600 m thick. Using aircraft and field expeditions, this ambitious project will collect major new data sets – including offshore marine, gravity, magnetics, ice radar and a wealth of geological observations – to produce a four-dimensional history of the evolution of the Gamburtsev mountains. As well as recovering samples from this last great unknown region of Antarctica, the project will shed new light on the origins of the Antarctic ice sheet and its role in future climate change.


{256} ANDRILL: Antarctic Continental Margin Drilling [ANDRILL]

Gary Wilson, University of Otago, New Zealand

ANDRILL is an international program involving scientists from Germany, Italy, New Zealand, the UK and the USA designed to investigate Antarctica's role in global environmental change from the recovery of rock and sediment cores from beneath the floating sea ice and ice shelves surrounding Antarctica.


{97} ICECAP: Investigating the Cryospheric Evolution of the Central Antarctic Plate [ICECAP]

Donald Blankenship, Institute for Geophysics, University of Texas, USA

ICECAP will undertake the first detailed airborne geophysical analysis of the Dome A and Dome C regions of central East Antarctica , and the Aurora Subglacial Basin to the north of Dome C. Extensive radio-echo sounding (RES) will allow us to measure the ice thickness, englacial structure, subglacial topography, subglacial lakes and basal thermal conditions of these regions.


{54} ACE: Antarctic Climate Evolution [ACE]

Robert Dunbar, Stanford University, USA

The ACE programme aims to facilitate research in the broad area of Antarctic climate evolution. The programme will link geophysical surveys and geological studies on and around the Antarctic continent with ice-sheet and climate modelling studies. These studies are designed to investigate climate and ice sheet behaviour in both the recent and distant geologic past, including times when global temperature was several degrees warmer than today.


{452} EBESA: Environmental, Biological, and Ecological Studies in Antarctica

Roberto Bargagli, Dept. of Environmental Biology, University of Siena, Italy

EBESA will study the effects of climatic and environmental changes, and the impact of man-made contaminants, on organisms and ecosystems of northern Victoria Land, James Ross Island, and Patagonia.


{170} Aliens in Antarctica

Dana Bergstrom, Department of Envionment and Heritage, Australian Antarctic Divison, Australia

Focusing on the annual migration of scientists and tourists to the Antarctic in 2007, this project will take samples from clothing and equipment to provide a unique snapshot of the number of spores, seeds, invertebrates and eggs transported to the continent: the first time that an assessment of the extent of transfer of alien species into an entire biome has ever been made.


{34} Impact of climate-induced glacial melting on marine and terrestric coastal antarctic communities [de]

Doris Abele, Alfred Wegener Institute for Polar and Marine Research, Germany

The Antarctic Peninsula is one of the Earth’s three most rapidly warming regions: most of the glaciers there are in retreat and large ice shelves have broken up. This project investigates the impact of these changes on the plants and animals that live on the land, the shore and coastal sea around the Antarctic Peninsula.


{341} Taking the Antarctic Arctic Polar Pulse-IPY 2007-8 Human Biology and Medicine Research

Jeff Ayton, SCAR SSG-Life Sciences: Expert Group Human Biology and Medicine, Australia

By collecting data for a new epidemiological database of health events in Antarctica, this 18-nation project will improve our understanding of how individuals and groups interact in confined environments, and how human physiology adapts to such extreme conditions.


{83} SCAR-MarBIN: Linking, Integrating and Disseminating Marine Biodiversity Information [SCAR-MarBIN]

Claude De Broyer, Royal Belgian Institute of Natural Sciences, Belgium

SCAR-MarBIN (SCAR Marine Biodiversity Information Network) establishes and supports a distributed system of interoperable databases, forming the Antarctic Regional OBIS Node, under the aegis of SCAR (Scientific Committee on Antarctic Research).


{53} CAML: Census of Antarctic Marine Life [CAML] [de]

Michael Stoddart, Administrator, CAML, Australia

The Census of Antarctic Marine Life will investigate the distribution and abundance of Antarctic marine biodiversity, how it will be affected by climate change and how climate change will affect the ecosystem and the planet.


{66} ANDEEP-SYSTCO:Antarctic benthic deep-sea biodiversity: colonisation history and recent community [ANDEEP-SYSTCO] [de]

Angelika Brandt, Zoological Institute and Museum, University of Hamburg, Germany

This 12-nation project will operate from RS Polarstern and use innovative technology including novel plankton and bottom samplers, landers, cameras and satellites to gather data on the marine pelagic and benthic fauna, sediment characteristics and physical oceanography from previously unexplored depths of the Southern Ocean.


{137} EBA: Evolution and Biodiversity in the Antarctic: The Response of Life to Change [EBA]

Guido di Prisco, Institute of Protein Biochemistry, CNR, Naples, Italy

The SCAR-programme EBA (2004-13) will address the impacts of climate change on species biodiversity, evolutionary adaptations and depletion of marine fisheries on community dynamics in the Southern Ocean.


{8} SASSI: Synoptic Antarctic Shelf-Slope Interactions Study [SASSI]

Karen Heywood, School of Environmental Sciences, University of East Anglia, UK

Involving a team of scientists from 11 countries, this project will measure the temperature, saltiness and flow speed of the water from continental shelf and slope, including under ice environments.


{81} Collaborative Research into Antarctic Calving and Iceberg Evolution

Hartmut Hellmer, Alfred Wegener Institute for Polar and Marine Research, Germany

CRAC-ICE will be a coordinated investigation into calving processes on three major Antarctic ice shelves, and a (long-term) monitoring of icebergs in the Southern Ocean, including the study of the physical processes related to iceberg drift and decay.


{313} PANDA: Program of Antarctic Nova Disciplines Aspects

Zhanghai Zhang, Polar Research Institute of China, China

The 2000 km interconnected Prydz Bay-Amery Ice Shelf-Lambert Basin-Dome A (PANDA) section in Antarctica plays an important role in Antarctic mass balance, sea level and climate change. About thirty observation systems for glaciology, oceanography, geology/geophysics, sun-earth physics, atmospheric science and astronomy will be installed and implemented along the section by the international cooperative expeditions leading by China during IPY 2007-2009 and beyond.


{42} SALE-UNITED: Subglacial Antarctic Lake Environments - Unified International Team for Exploration and Discovery [SALE-United] [de]

Mahlon C. Kennicutt II, Texas A&M University, USA

The most intriguing questions relate to who lives in these environments and how do they make a living. The presence of microbial ecosystems is almost assured and how they have survived at the edge of life will provide clues to where we might find life elsewhere in the solar system.

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Um die Ansprüche von Cook (1908) und Peary (1909) auf das Erreichen des Nordpols zu überprüfen, unternahm Wally Herbert 1968/69 eine 16-monatige Expedition mit Schlittenhunden von Alaska über den Nordpol nach Spitzbergen. Es war die erste Arktisüberschreitung. Sie wurde aus der Luft versorgt.

Da Herbert die Ansprüche von Cook und Peary in Zweifel zog, beanspruchte er, in der Tradition machistisch-infantiler Erster-Spiele, zudem den Titel des ersten, der den Nordpol erreichte.

72jährig starb Herbert, der auch Autor und Maler war, am 12. Juni 2007 in Inverness, Schottland.

The poles.com bringt den bei weitem besten Nachruf.

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Dienstag, den 12. Juni 2007, ist Arved Fuchs vom Flensburger Museumshafen aus mit seinem Haikutter "Dagmar Aaen" und einer internationalen Crew mit Kurs auf Spitzbergen in See gestochen.

Auszüge aus der Pressemitteilung vom 11. Juni 2007:

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Seit Dezember 2004 befürwortet die kanadische Regierung die Selbstverwaltung der natürlichen Ressourcen der Nördlichen Territorien durch die Nunavut-Regionalregierung. Ein gerade veröffentlichter Bericht belegt, dass die personellen Voraussetzungen zur Übernahme der Administration noch nicht gegeben sind.

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Norwegische und französische Forscher haben mehr als 4'000 DNA-Profile von neun auf Spitzbergen heimischen Blütenpflanzen untersucht und dabei genetische Muster gefunden, die belegen, dass Pflanzengemeinschaften während der letzten 20'000 Jahre immer wieder neu aus Samen weit entfernter Gebiete wie Russland und Grönland aufwuchsen, sobald die klimatischen Bedingungen auf Spitzbergen es erlaubten. Daraus schliessen die Forscher, dass arktische Pflanzen grosse Distanzen überwinden können, um dem Klimawandel entsprechende ökologische Nischen zu finden.