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A study has provided insight into copper sulfate pentahydrate and could give clues to how other hydrated minerals change under the pressures within planetary environments

Ultra small angle neutron scattering on Kookaburra is used to study the size and shape of objects of size 10 micrometres and below.

Taipan is used to study the collective motion of atoms, phonons and magnons in materials, and phase transitions and processes involving thermal energy.

Dr Mitra Safavi Naeini continues her commentary of the radiation studies being undertaken in the Artemis II mission.

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.

The Infrared Microspectroscopy beamline combines the high brilliance and collimation of the synchrotron beam through a Bruker V80v Fourier Transform Infrared (FTIR) spectrometer and into a Hyperion 3000 IR microscope to reach high signal-to-noise ratios at diffraction limited spatial resolutions between 3-8 μm.

ANSTOs capabilities are ideally suited for these investigations relating to quantum technologies.

In Australia and the Southeast Asia basin, the ANSTO facility offers a wide range of unique nuclear-beam techniques for cultural heritage research.

ANSTO researchers have demonstrated longstanding expertise in the study of nuclear fuel and radioactive waste with two recent journal articles in a special issue of Frontiers of Chemistry.

Accelerator technique used in pioneering biomaterials research led by the University of Sydney.

Using neutron imaging techniques at ANSTO, researchers from Macquarie University have gained a better understanding of how corrosion forms and spreads through concrete that is commonly used in sewer pipes.

Recently, a small delegation, including Yandruwandha Yawarrawarrka representatives from the remote outback settlement of Innamincka SA, travelled to ANSTO to deliver rare wooden Aboriginal archaeological artefacts for measurements to determine their age and origin.

The mechanical, electrical, chemical, optical and thermal properties of glass, as determined by its chemical composition and atomic structure, make it a highly useful material with a myriad of applications.

When an energetic ion beam hits a sample it will interact with the atoms through a number of very complex interactions. By detecting and measuring the reaction products resulting from the various interactions and their intensities, you can obtain quantitative data on the sample's constituent elements and their spatial distribution.

Radioisotopes are widely used in medicine, industry, and scientific research. New applications for radioisotopes are constantly being developed.