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A collaborative group including Monash has produced an ultra-thin and ultra-flexible organic solar cell for advanced wearable devices.

Funding awarded for research on an additive manufacturing technique for use on rail infrastructure.

ANSTO participation in ARC on Intelligent Robotic Systems for Real-time Asset Management has potential benefit in the management of infrastructure and assets

Using isotopes to understand saltwater intrusion of Rottnest Island groundwater

ANSTO is a partner on the National Space Qualification Network (NSQN) led by the Australian National University (ANU) that will transform Australia into a world-leading space centre by enhancing facilities to test payloads, components, and hardware prior to their use in harsh environments of space.

Indigenous Kakadu plum farmers attend workshop on use and application of the elemental fingerprint technology for indigenous bushfoods provenance.

Research reports for the first time how solid methane and nitrogen expand in response to temperature changes and resolves an historic ambiguity relating to the structure of nitrogen.

The process by which plastic degrades in the ocean facilitates its entry into the natural carbon cycle efficiently as carbon dioxide.

ANSTO provides a range of capabilities using neutrons, X-rays and infrared radiation to study the solids, liquids and gases that might be found in materials in our solar system and beyond.

The first experimental evidence to validate a newly published universal law that provides insights into the complex energy states for liquids has been found using an advanced nuclear technique at ANSTO.

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

A unique scientific capability comprising a single research platform for high-fidelity simulation, real-time dosimetry, and biological response data is available all from a neutron instrument.

A new study by researchers from Curtin University using the infrared (IR) and X-ray fluorescence microscopy (XFM) beamlines at the Australian Synchrotron has provided a better understanding of the chemical and elemental composition of latent fingermarks.