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Unique landmark instrumentation and expertise are a hallmark of ANSTO’s sovereign capability, unavailable anywhere else in Australia.  Our ability to identify the source of hazardous particulates in air, the age of water in aquifers and the detailed chemistry of toxic elements in complex soil and biota specimens are just some examples of ANSTO capability.

ANSTO conducts and enables research to address some of Australia’s and the world’s most challenging environmental problems.

Project focuses on enhancing crop productivity in Asia Pacific countries by improving soil and water.

Today is World Environment Day, a United Nations initiative for encouraging worldwide awareness and action for the environment. This year’s theme is “Beat Air Pollution”, a call to action to combat this global crisis.

ANSTO is committed to minimising the environmental impact of its activities and to implementing strategies which have a positive effect on the environment. The ANSTO Work Health Safety and Executive Committee oversees this process.

The Australian Centre for Neutron Scattering maintains a sample environment service for the instruments. It comprises a range of sample environments, two sample environment laboratories and four sample preparation laboratories.

ANSTO has produced a comprehensive report for the NSW Department of Planning and Environment that represents a significant scientific investigation of the connections, pathways and processes of water loss from the Thirlmere Lakes system.

ANSTO has put together a robust multidisciplinary approach to understanding the impacts of nanomaterials, investigating a common food additive, E171 titanium dioxide, used primarily as a colouring agent in everyday foods. 

Radiocarbon measurements at ANSTO’s Centre for Accelerator Science have supported research published that provided insights into what the environment was like for the Aboriginal artists who created rock art over intervals spanning 43,000 years.

A cross-disciplinary team has used laboratory-based and synchrotron-based infrared spectroscopy imaging techniques to monitor the waxy surface of living plant leaves in real-time to gain insights into plant physiology in response to disease, biological changes or environmental stress.