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Climate models, weather data, oceanography, hydrology, atmospheric science, environmental monitoring
26,690 datasets
Nearly 1.4 million gravity stations from the Australian National Gravity Database were used to generate this spherical cap Bouguer anomaly grid. The grid has a cell size of 0.00417 degrees (approximately 435 meters) and presents data in units of micro-meters per second squared. Compiled by Geoscience Australia using ground observations as of September 2019 and supplemented with offshore data.
Approximately 1.8 million gravity observations, including nearly 1.4 million land stations, underpin this 2019 compilation. The Australian Ocean Data Network processed and quality-checked these data, which combine ground surveys from the 1940s onward with offshore data from Scripps Institution of Oceanography. The resulting grid has a cell size of 0.00417 degrees (about 435 meters) and shows complete Bouguer anomalies over Australia and its margins.
National Gravity Compilation 2019 CSCBA image is a gravity anomaly grid derived from nearly 1.4 million ground stations in the Australian National Gravity Database and offshore data. The grid has a cell size of 0.00417 degrees (approximately 435m) and presents data in units of micro-meters per second squared. It was compiled by Geoscience Australia using data acquired from the 1940s to September 2019 from government, industry, and academic sources.
The Australian Ocean Data Network hosts data on interactions at methane seeps, last updated on 2026-04 10. The description details the role of methane in the carbon cycle, microbial oxidation processes, and the influence of fluid flow on benthic communities. The dataset likely contains measurements from cold seep sites along continental margins.
Nearly 1.4 million gravity stations from a national database were used to generate this continental-scale grid. The Australian Ocean Data Network compiled ground and offshore data acquired from the 1940s onward, releasing this processed tilt grid in 2019. It provides a detailed geophysical model of Australia and its continental margins with a spatial resolution of approximately 435 meters.
Australia's 2019 National Gravity Compilation grid contains approximately 1.8 million gravity observations processed to reveal sub-surface geological structure. The grid is derived from nearly 1.4 million ground stations in the Australian National Gravity Database, supplemented by offshore data, with ground station spacing ranging from 11 km to less than 1 km. It was produced by Geoscience Australia from data collected by government, industry, and research organizations from the 1940s onward.
2019 data compiled from nearly 1.4 million gravity stations and marine data, spanning observations from the 1940s to September 2019. The grid shows the half vertical derivative of de-trended global isostatic residual anomalies over Australia and its margins. It was produced by Geoscience Australia from the Australian National Gravity Database and global marine sources.
Nearly 1.4 million gravity stations from the Australian National Gravity Database, supplemented by marine data, were used to generate this grid. The grid shows de-trended global isostatic residual anomalies over Australia and its continental margins, derived from observations dating from the 1940s to 2019. Data were processed and quality-checked by Geoscience Australia geophysicists.
Over 1.8 million gravity observations from the 1940s to 2019 underpin this national compilation grid. The grid provides de-trended global isostatic residual anomalies over Australia and its continental margins at a 0.00417-degree cell resolution. The Australian Ocean Data Network released this processed data, derived from the Australian National Gravity Database and supplemented by global marine data.
Australia and its continental margins are covered by this gravity anomaly image derived from nearly 1.4 million ground and marine observations. The grid has a cell size of approximately 435 meters and shows de-trended global isostatic residual anomalies. Data were compiled from the Australian National Gravity Database as of September 2019, supplemented by global marine data, with ground observations collected from the 1940s to the present day.
Australia and its continental margins are covered by a gravity anomaly grid with a 435-meter cell resolution. The grid integrates nearly 1.4 million ground stations from the national database and offshore data, compiled by Geoscience Australia and partner organizations. It represents the first vertical derivative of de-trended isostatic residual anomalies, processed from data collected from the 1940s to 2019.
A gravity anomaly grid derived from approximately 1.8 million ground and marine gravity observations across Australia. The grid has a cell size of 0.00417 degrees (approximately 435m) and was compiled by Geoscience Australia using data from government, industry, and research sources collected from the 1940s onward. The final 2019 compilation integrates terrestrial data from the Australian National Gravity Database with offshore data from the Scripps Institution of Oceanography.
Over 1.8 million gravity observations underpin this 0.5 vertical derivative grid of Australia. Data integrates 1.4 million ground stations with 345,000 line km of airborne gravity and 106,000 line km of airborne gradiometry surveys. The grid was compiled by Geoscience Australia using data from government, industry, and academia, with observations spanning from the 1940s to 2019.
Gravity data measures density variations in subsurface rocks to reveal geological structure. The compilation integrates nearly 1.4 million ground stations from a national database and offshore sources, processed into a grid with a 0.00417-degree cell size. The grid was generated by Geoscience Australia and partners using data collected from the 1940s to 2019.
Projected relative changes in mean precipitation for the period 2081-2100 compared to a 1986-2005 baseline. The map data represents the median projection from an ensemble of CMIP5 climate models under the RCP8.5 scenario. It was produced by Environment and Climate Change Canada and was last updated in April 2026.
A free air gravity anomaly grid for Australia and its continental margins measures variations in gravitational acceleration due to subsurface rock density. The grid integrates nearly 1.4 million ground stations from the national database and offshore data, with station spacing from less than 1 km to 11 km. It was compiled by Geoscience Australia using data from government, industry, and research sources collected from the 1940s to September 2019.
A 2019 compilation grid derived from approximately 1.8 million gravity observations, including nearly 1.4 million ground stations from the Australian National Gravity Database and supplemented by offshore data. The grid, with a cell size of 0.00417 degrees (~435m), shows the tilt of de-trended global isostatic residual anomalies over Australia and its margins. It was produced by Geoscience Australia from data acquired by government, industry, and research entities from the 1940s onward.
Over 1.8 million gravity observations, including nearly 1.4 million ground stations and 451,000 line kilometers of airborne surveys, were compiled to create this grid. The Australian Ocean Data Network released this dataset, which integrates ground, airborne, and offshore gravity data up to September 2019. It represents the tilt filter of complete Bouguer anomalies across Australia and its continental margins.
2019 compilation integrates gravity data from the 1940s to present. The dataset combines approximately 1.8 million ground observations, 345,000 line km of airborne gravity, and 106,000 line km of airborne gravity gradiometry to model subsurface geology. It was produced by Geoscience Australia from the Australian National Gravity Database and global sources.
A review from the Australian Ocean Data Network synthesizes available information on the effects of climate change on noncoral tropical benthic invertebrates. The work, last updated in April 2026, creates a framework to predict vulnerability and adaptive capacity. It focuses on environmental stressors like increasing sea surface temperatures and their links to ecological processes.