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Nuclear science is crucial to understanding our universe, our world and ourselves at the atomic level. If we can understand how atoms get together, interact, or can be best combined with other atoms, new, more efficient materials and drugs can be developed.

Modifications to promising novel non-fullerene small molecule acceptor in organic thin film for solar cells demonstrates improved power conversion efficiency.

ANSTO has a range of capabilities and expertise to support aerospace and space research.

An international team of academic researchers led by Curtin University have provided a description of a new species of pterosaur, a flying reptile.

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.

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.

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

ANSTO Synroc technology provides a safe, secure matrix for the immobilisation and final disposal of radioactive waste.

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.

Atomic structure of new cathode material for sodium ion batteries helps explain long life