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The Medium Energy- X-ray Absorption Spectroscopy beamlines will provide access to XANES and EXAFS data from a bending magnet source, optimised for cutting-edge applications in biological, agricultural and environmental science in an energy range that is not currently available at the Australia Synchrotron.

ANSTO provides a summary of water usage and discharge for FY2022 - FY2023

Principal Technical Consultant Michael Druce shares some personal insights on the design and construction of ANSTO's nuclear medicine facility.

Using nuclear techniques to help sustain Australia's finite groundwater resources

Study shows for the first time that vegetation in the Windmill Islands, East Antarctica is changing rapidly in response to a drying climate.

Researchers and industry partners from UNSW Australia, the Australian Centre for Nanomedicine, Children’s Cancer Institute and Inventia Life Sciences Pty Ltd have been awarded the 2021 ANSTO Eureka Prize for Innovative Use of Technology for their method to rapidly-produce 3D cell structures

The Australian Centre for Neutron Scattering (ACNS) is a major research facility for neutron science that comprises a suite of neutron instruments with a range of techniques for scientific investigations in physics, chemistry, materials science, medicine and environmental science among other fields.

Radiation can be described as energy or particles from a source that travel through space or other mediums. Light, heat, and wireless communications are all forms of radiation.

The final report on the safety of Building 23 by the independent expert review team has been completed.

Highlights of the Magnetism Project.

ANSTO facilitating coordinated effort to find the nexus that leads to chronic kidney disease of unknown origin

The X-ray Fluorescence Nanoprobe beamline undertakes high-resolution X-ray microspectroscopy, elemental mapping and coherent diffraction imaging – providing a unique facility capable of spectroscopic and full-field imaging. Elemental mapping and XANES studies will be possible at sub-100 nm resolution, with structural features able to be studied down to 15 nm using scanning X-ray diffraction microscopy.

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

With enhanced submicron spatial resolution, speed and contrast, the Micro-Computed Tomography beamline opens a window on the micron-scale 3D structure of a wide range of samples relevant to many areas of science including life sciences, materials engineering, anthropology, palaeontology and geology. MCT will be able to undertake high-speed and high-throughput studies, as well as provide a range of phase-contrast imaging modalities.