Highlights - Cultural Heritage
Over the last decades, neutron, photon, and ion beams have been established as an innovative and attractive investigative approach to characterise cultural-heritage materials.
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Over the last decades, neutron, photon, and ion beams have been established as an innovative and attractive investigative approach to characterise cultural-heritage materials.
Publications and resources from the Powder Diffraction beamline.
The need for a smaller, more transportable version of ANSTO’s 1500-litre atmospheric radon-222 monitor, and with a calibration traceable to the International System of Units, prompted the team to develop a 200-litre radon monitor that would meet those needs.
Highlights of the Energy Materials Project.
ANSTO has been tracking and publishing data on fine particle pollution from key sites around Australia, and internationally, for more than 20 years.
Read about an ANSTO scientist and their work to prepare for a school project or interview.
The Infrared microspectroscopy microscopes can record spectra from a range of different samples; from thin microtomed sections to polished blocks and embedded particles. This section highlights the types of samples that can be analysed using the IRM beamline
Thirty years of ANSTO's unique capability in monitoring fine particle pollution provides insight on bushfire smoke.
Charcoal particles from recent bushfires in NSW were carried 50 kilometres by the wind, which has significance for fire history reconstruction.
Useful in some mineral processes but a major problem in others, jarosite may be the key to unlocking the geological history and environmental context of water on Mars.
Planning is now underway for a second repatriation project which is scheduled to take place in 2022. Find out more information.
Publications, posters and conference presentations for fire impacts reconstructed from a southwest Australian stalagmite.
Australia’s Open Pool Australian Lightwater (OPAL) reactor is a state-of-the-art 20 megawatt multi-purpose reactor that uses low enriched uranium (LEU) fuel to achieve a range of activities to benefit human health, enable research to support a more sustainable environment and provide innovative solutions for industry.
A world-class national research facility that uses accelerator technology to produce a powerful source of light-X rays and infrared radiation a million times brighter than the sun.