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ANSTO provides access to specialised facilities and capabilities by application. Please ensure that you contact the relevant ANSTO scientist for advice before submitting a proposal.

The User Advisory Committee (UAC) are pleased to present this year's invited speakers.

Cracking the code for crop nutrition and food quality with X-ray fluorescence microscopy.

A team of researchers including the University of Rochester, CSIRO and ANSTO has found methane emissions from human fossil sources have been greatly underestimated.

The High Performance Macromolecular Crystallography beamline will enable the study of very small (sub-5 micrometre) or weakly diffracting crystals, providing a state-of-the-art high-throughput facility for researchers. MX3 will be able to study the structures of large proteins and protein complexes for virology, drug design and industrial applications via goniometer mounted crystals, in-tray screening, or via serial crystallography methods.

Publications and resources from the Powder Diffraction beamline.

Neutron Capture Enhanced Particle Therapy developed at ANSTO.

ANSTO has been tracking and publishing data on fine particle pollution from key sites around Australia, and internationally, for more than 20 years.  

A large collaboration of Australian and New Zealand researchers has established that a thin film technology can be used to monitor stormwater effectively and provides a way to translate the presence of metal contaminants into potential risks to aquatic ecosystems.

The Advanced Diffraction and Scattering beamlines (ADS-1 and ADS-2) are two independently operating, experimentally flexible beamlines that will use high-energy X-ray diffraction and imaging to characterise the structures of new materials and minerals.

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.