Ion Beam Induced Spatio-temporal Structural Evolution of Materials: Accelerators for a New Technology Era

Closed for proposals

Project Type

Coordinated Research Project

Project Code

F11020

CRP

2153

Approved Date

14 September 2016

Start Date

7 December 2016

Expected End Date

30 June 2022

Completed Date

11 January 2023

Participating Countries

Australia
China
Croatia
Finland
India
Italy
Japan
Singapore
Spain
United States of America

Description

Time and spatially-resolved ion beam irradiation techniques play an important role in modifying the properties and patterning of several classes of materials. Over the past decade there has been a widespread reappraisal of fundamental quantum mechanical principles for their potential to be exploited in engineered devices for new functions. To improve utilization of these ion beam techniques for tuning material properties for quantum technologies requires the development of new experimental techniques and the refinement of theoretical models with an aim to deepen the understanding of radiation effects and ion interaction processes. Direct experimental access to the dynamics of radiation induced defects, from femto-seconds to seconds, has been elusive. Therefore this CRP is proposed to contribute towards greater understanding of the multi-scale dynamics of radiation effects created by ion beams in order to design materials with tailored responses to radiation, from radiation hardness to the engineering of desired defects.

Objectives

To develop novel accelerator-based ion beam tools to induce and characterise effects in the spatial- and time domains for tailoring materials properties and thus creating new materials towards quantum technologies.

Specific objectives

Provision of strategies for creating and employing modified materials for novel devices with superior attributes compared to existing devices.

To tackle scalability and integration of quantum devices with new fabrication and characterisation methods that build on established ion beam techniques.

Improved understanding and modelling of the multi-scale dynamics of radiation effects from femto-seconds to seconds.

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