Search results

Consumers want to know that the foods they consume provide health benefits. Food materials science can monitor changes during digestion as well as assist in the development of low-fat products.

Following your experiment at the Australian Synchrotron there are certain tasks that users can complete including a user feedback survey and claiming reimbursement for travel expenses.

ANSTO Big Ideas encourages students to creatively communicate the work of an Australian scientist, and explain how their work has inspired them to come up with a Big Idea to make our world a better place. This competition is intended to engage and support Australian students in years 7-10 in Science and encourage them to pursue studies and careers in STEM.

Over the last decades, neutron, photon, and ion beams have been established as an innovative and attractive investigative approach to characterise cultural-heritage materials.

ANSTO announces the recipients of the 2022 organisational awards

ANSTO’s nuclear medicine processing and distribution facility assembles, loads, tests and distributes a range of nuclear medicine products, including Mo-99. The Mo-99 is dispensed into an ANSTO radiopharmaceutical Gentech® Generator where it decays to Tc-99m.

The BRIGHT Nanoprobe beamline provides a unique facility capable of spectroscopic and full-field imaging. NANO will undertake high-resolution elemental mapping and ptychographic coherent diffraction imaging. Elemental mapping and XANES studies (after DCM upgrade) will be possible at sub-100 nm resolution, with structural features able to be studied down to 15 nm using ptychography.

The Biological Small Angle X-ray Scattering beamline will be optimised for measuring small angle scattering of surfactants, nanoparticles, polymers, lipids, proteins and other biological macromolecules in solution. BioSAXS combines combine a state-of-the-art high-flux small angle scattering beamline with specialised in-line protein purification and preparation techniques for high-throughput protein analysis.

Study helps make carbon dating a more accurate chronological tool.

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 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.

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

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.

Latest information on the scheduled supply of our nuclear medicine production.

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.