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Technique provides insights into historic maritime artefact linked to early exploration of Australia.

From June to August we invited primary schools in Greater Sydney/Illawarra and Melbourne to participate in our 2019 Shorebirds Competition. Students in Years 3 to 6 were asked to create a public awareness poster for a threatened shorebird found in Australia.

Restoring soil carbon can bring benefits for agricultural productivity and climate change mitigation.

ANSTO contributes to major study on global warming by measuring methane and carbon monoxide trapped in ice.

The Australian Synchrotron provides funding support for successful beamtime applicants in the form of travel funding and/or onsite accommodation. Travel funds granted are to be used solely to cover the majority of the cost to travel to the AS facility. The User Office will book accommodation for interstate user groups at the onsite AS Guesthouse.

The National Deuteration Facility offers access to deuterated molecules prepared by both in vivo biodeuteration and chemical deuteration techniques.

Scientists at ANSTO characterise structures with atomic detail using probes such as x-rays, electrons, neutrons and ions.

Recoil Time of Flight Spectrometry (RTOF) is used to detect a multitude of elements by separating their masses. unambiguously

Cyclotek and ANSTO have announced the launch of a Joint Venture (JV), to establish Australia’s first GMP (Good Manufacturing Practice) theranostics facility starting in Melbourne, Australia.

Dr Mathew Johansen, an environmental scientist at ANSTO, presented in an online IAEA training workshop on Advanced Topics in Radiochemistry Techniques this week.

Technical information on the SAXS / WAXS beamline at the Australian Synchrotron.

Virtual activities celebrating the benefits of nuclear science and technology held for National Science Week

The installation of a cold neutron source (CNS), a component that reduces the energy and speed of the neutrons from a research reactor for use in scientific instruments, was successfully completed in September 2024.

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.