Publicly available bathymetry and geophysical data can be used to map geomorphic features of the Antarctic continental margin and adjoining ocean basins at scales of 1:1-5 million. These data can also be used to map likely locations for some Vulnerable Marine Ecosystems. Seamounts over a certain size are readily identified and submarine canyons and mid ocean ridge central valleys which harbour hydrothermal vents can be located. Geomorphic features and their properties can be related to major habitat characteristics such as sea floor type (hard versus soft), ice keel scouring, sediment deposition or erosion and current regimes. Where more detailed data are available, shelf geomorphology can be shown to provide a guide to the distribution in the area of the shelf benthic communities recognised by Gutt (2007). The geomorphic mapping method presented here provides a layer to add to benthic bioregionalistion using readily available data. An AADC maintained copy of these data are publicly available for download from the provided URL. The master copy of these data are attached to the metadata record held at Geoscience Australia (see the provided URL).

The Australian Antarctic Division holds a collection of approximately 5,500 maps and charts. A catalogue of its holdings can be searched in detail and viewed in the SCAR Antarctic Map Catalogue. The Map Catalogue includes many historical maps dating back to the mid 1800's, thematic maps such as geological, vegetation and bathymetry maps, hydrographic charts, topographical maps, satellite image maps and orthophoto maps. Maps for work purposes are provided to Antarctic Expeditioners and AAD staff free of charge. Members of the public may be directed to mapping sales outlets. Contact the technical officer (below) for details. Many maps in the catalogue are digital maps available for download. These maps are provided free of charge. The Data Centre employs a Map Curator for adding, updating and correcting map references. The Map Curator is also responsible for storing and manageing the physical copies of maps in the Data Centre Map store. If there are any errors, please advise the Data Centre using the links on the Map Catalogue page.

Detailed sedimentary information and palaeontological samples were collected from Battye Glacier Formation, of the Pagodroma Group in the Prince Charles Mountains, an area where little information is presently available. The mid to Upper Cenozoic Pagodroma Group provides direct evidence for past changes in climate and glacial environments from deep within the Antarctic continent. Evidence from several geological formations in the Pagodroma Group, many of them fossil-bearing, will help to determine the history of fluctuations in climate and the size of the East Antarctic Ice Sheet (EAIS). This will provide baseline data to help validate the predictive numerical models of ice sheet dynamics. There is a clear need to study the response of the EAIS to past times of global warming. Periods of significance include times when atmospheric CO2 levels were similar to today (Poore and Sloan 1996). Another key time interval is during the late Neogene, prior to the development of Northern Hemisphere glaciation, which has largely governed Antarctic Ice Sheet volume changes during the Quaternary (Clapperton and Sugden 1990; Mabin 1990; Huybrechts 1990, 1992). An important aspect of the research is to build onto the geological data-set collected by ODP Leg 119, 120 and 188 in Prydz Bay. These operations have concentrated on the periphery of Antarctica and, therefore, record ice sheet retreat and advance at its outer-limits. The Pagodroma Group provides significant information about ice sheet variation at its the inner reaches. Together, these data-sets will shape our understanding of major fluctuations of the ice sheet through the Cenozoic, and will assist and test the models developed to predict ice sheet behavior in the future. Direct geological evidence for climatic conditions and the extent of the ice sheet during times of glacial retreat can be obtained only from onshore geological records, such as the Pagodroma Group. This is important given the current warming trends, expected ice sheet retreat and global sea-level rise, and general lack of geological data from onshore Antarctica for predicting the effects of this on the EAIS. Fieldwork was conducted during November - December (2000). A number of significant findings were made from the Amery Oasis: 1) New outcrops of the glacio-marine Battye Glacier Formation were located and mapped. Up to 800 m of geological section was logged and sampled. Similar Antarctic records have only been made available through expensive international drilling efforts around the Antarctic shelf. This project highlights that there are extensive records exposed on land, that can be studied for a fraction of the cost of off-shore marine geoscience. 2) Unique diatomaceous marine mudstone deposits were discovered (~9 m thick). This is the most diatomaceous (up to 12% biogenic silica), in situ marine deposit that has have been found from inland Antarctica. Diatom biostratigraphy indicates that the formation is middle - late Miocene in age. 3) In situ and articulate marine mollusc fossil horizons were discovered. These occur over a lateral distance of ~ 1km and provide undisputable evidence for a major ice sheet retreat in the past. 4) Three erratics containing marine mollusc fossils were discovered. These erratic are potentially Cretaceous in age (Stilwell, pers. comm.). This is the first marine sediment of this age found in the Lambert Graben catchment. Eleven pdf figures are available for download from the provided URL. Also included is a text file which explains what each of the figures are. Furthermore, two excel spreadsheets of data are also available. The two excel spreadsheets in the download directly relate to the paper Whitehead, et al (2003). Some explanatory notes for the excel files are: Qualitative assessment of fossil preservation vf = very fragmented with a few intact specimens seen per traverse of a microscope slide. mf = moderately fragmented with an intact specimen seen every few fields of view (at 600x magnification). See Whitehead et al (2003) for more information. Qualitative fossil abundance, where X = (present) one valve (Diatom valves)/fossil seen during entire examination. R = (rare) greater than 3 valves/fossils seen during all microscope traverses on slide. F = (few) greater than 1 valve/fossil per 10 microscope fields of view (at 600x magnification). C = (common) valves/fossils in each microscope field of view (at 600x magnification). The fields in this dataset are: Stratigraphic Intervals Samples Opal% McLeod Beds Bed A clasts Fossil Preservation Benthic Diatom Abundance Species Bardin Bluffs Formation Fisher Bench Formation Diatoms

Taken from sections of the report: In recent years, Geoscience Australia (GA) has increased its capability on the Antarctic continent with the installation of Continuous Global Positioning System (CGPS) sites in the Prince Charles Mountains and Grove Mountains. Over the course of the 2006/07 Antarctic summer, Alex Woods and Nick Brown from Geoscience Australia (GA) collaborated with Dan Zwartz of the Australian National University (ANU) to install new CGPS sites at the Bunger Hills and Richardson Lake and perform maintenance of the CGPS sites at the Grove Mountains, Wilson Bluff, Daltons Corner and Beaver Lake. The primary aim of the CGPS sites is to provide a reference frame for Antarctica, which is used to determine the long-term movement of the Antarctic plate. Data from Casey, Mawson and Davis is supplied to the International GPS Service (IGS) and in turn used in the derivation of the International Terrestrial Reference Frame (ITRF). The sites also open up opportunities for research into post-glacial rebound and plate tectonics. In many respects CGPS sites in Antarctica are still in their infancy. Since the mid 1990's Geoscience Australia and the Australian National University have been testing new technology and various methods to determine the most effective way of running a CGPS site in Antarctica. A more detailed review of Australia's involvement in Antarctic GPS work can be found in (Corvino, 2004) In addition, a reconnaissance survey was undertaken at Syowa Station to determine whether a local tie survey could be performed on the Syowa VLBI antenna in the future. Upgrades were made to the Davis and Mawson CGPS stations and geodetic survey tasks such as reference mark surveys, tide gauge benchmark levelling and GPS surveys were performed at both Davis and Mawson stations. In addition, work requested by Geoscience Australia's Nuclear Monitoring Project, the Australian Government Antarctic Division (AGAD) and the University of Tasmania (UTAS) were completed. The 2006/07 Geoscience Australia Antarctic expedition proved to be one of the most successful Antarctic seasons by geodetic surveyors from Geoscience Australia. All intended field locations were visited and all work tasks were completed. Background The primary aim of the CGPS sites is to provide a reference frame for Antarctica, which is used to determine the long-term movement of the Antarctic plate. Data from Casey, Mawson and Davis is supplied to the International GPS Service (IGS) and in turn used in the derivation of the International Terrestrial Reference Frame (ITRF). The sites also open up opportunities for research into post-glacial rebound and plate tectonics. In many respects CGPS sites in Antarctica are still in their infancy. Since the mid 1990's Geoscience Australia and the Australian National University have been testing new technology and various methods to determine the most effective way of running a CGPS site in Antarctica. Dr John Gibson from The University of Tasmania requested that Alex Woods and Nick Brown collect moss samples from any locations visited during the Antarctic summer field season. While working in the field only a few moss specimens were found. No moss or lichen specimens were observed at locations such as Wilson Bluff, Dalton Corner, Beaver Lake or the Grove Mountains. Moss samples were collected at Richardson Lake and Mawson Station and these samples were frozen after collection and returned to Australia. This work contributed towards AAS (ASAC) project 1159.

The SCAR Spatial Data Model has been developed for Geoscience Standing Scientific Group (GSSG). It was presented to XXVII SCAR, 15-26 July 2002, in Shanghai, China. The Spatial Data Model is one of nine projects of the Geographic Information Program 2000-2002. The goal of this project is 'To provide a SCAR standard spatial data model for use in SCAR and national GIS databases.' Activities within this project include: 1. Continue developing the SCAR Feature Catalogue and the SCAR Spatial Data Model 2. Provide SCAR Feature Catalogue online 3. Creation and incorporation of symbology 4. Investigate metadata / data quality requirements 5. Ensure compliance to ISO TC211 and OGC standards Source: http://www.geoscience.scar.org/geog/geog.htm#stds Spatial data are increasingly being available in digital form, managed in a GIS and distributed on the web. More data are being exchanged between nations/institutions and used by a variety of disciplines. Exchange of data and its multiple use makes it necessary to provide a standard framework. The Feature Catalogue is one component of the Spatial Data Model, that will provide the platform for creating understandable and accessible data to users. Care has been taken to monitor the utility of relevant emerging ISO TC211 standards. The Feature Catalogue provides a detailed description of the nature and the structure of GIS and map information. It follows ISO/DIS 19110, Geographic Information - Methodology for feature cataloguing. The Feature Catalogue can be used in its entirety, or in part. The Feature Catalogue is a dynamic document, that will evolve with use over time. Considerable effort has gone into ensuring that the Feature Catalogue is a unified and efficient tool that can be used with any GIS software and at any scale of geographic information. The structure includes data quality information, terminology, database types and attribute options that will apply to any GIS. The Feature Catalogue is stored in a database to enable any component of the information to be easily viewed, printed, downloaded and updated via the Web.