Applications of Accelerators in the Quantum Technology Era

David Jamieson, Andrew Anthony Bettiol, André Schleife

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English

CRC Press
13 November 2024

This book explores new experimental techniques and theoretical models to deepen an understanding of radiation effects and ion interaction processes in order to design materials for devices for the emerging quantum technology era.

Applications include tailored sensors that respond to ionizing radiation and other electromagnetic phenomena; sensors with high radiation hardness; and materials that contain specific engineered defects with desirable optical, magnetic, or electrical properties.

The chapters detail direct experimental investigations into the dynamics of radiation-induced defects, including their generation, annihilation, and transformation, on a time scale ranging from femto-seconds to seconds which requires a more detailed understanding to develop the potential of ion beams for the new technology era.

It will be a valuable reference for graduate students and researchers that employ ion beams and want to engage in quantum technologies. The book will also be of interest to scientists and engineers from industry that want to make use of ion beams in quantum technologies or learn more about the potential use of ion beams in the field.

Key Features:

• Provides a comprehensive introduction to this exciting and growing field of research.

• Up-to-date with the latest cutting-edge research and practical guidance for researchers and those in industry to apply to their work.

• Edited by established authorities, with chapter contributions from subject-area specialists.

Edited by: David Jamieson, Andrew Anthony Bettiol, André Schleife
Imprint: CRC Press
Country of Publication: United Kingdom
Dimensions: Height: 234mm, Width: 156mm,
Weight: 480g
ISBN: 9781032310589
ISBN 10: 1032310588
Pages: 162
Publication Date: 13 November 2024
Audience: College/higher education , Professional and scholarly , Primary , Undergraduate
Format: Hardback
Publisher's Status: Forthcoming

Chapter 1: Introduction to Ion Beams and Quantum Technology. Chapter 2: Predictive Simulations of Electronic and Atomic Phenomena of Particle Radiation. Chapter 3: Introduction to Single Ion Techniques with Focused Ion Beams. Chapter 4: Quantum Communication and Sensing Based on Color Centers in Wide Bandgap Semiconductors. Chapter 5: Ion Irradiation of Ultrathin Materials. Chapter 6: Single Implanted Ions for Qubits: Technology and Applications. Chapter 7: Dynamics of Radiation Effects in Silicon Studied with Pulsed Ion Beams and Ion Beam Induced Charge Collection.

David Jamieson is a Professor of Physics at the University of Melbourne. He served as President of the Australian Institute of Physics from 2005 to 2006 and is a Fellow of the AIP and the Institute of Physics UK. From 2008 to 2013, he served as the Head of the School of Physics at the University of Melbourne. His research expertise in the field of ion beam physics was applied to test some of the key functions of a revolutionary quantum computer constructed in silicon at the Australian Research Centre of Excellence for Quantum Computation and Communication Technology where he is a chief investigator and programme manager. Andrew Anthony Bettiol is an Associate Professor at the National University of Singapore. He is a principal investigator at the Centre for Ion Beam Applications (CIBA), Singapore, a multi-disciplinary research centre aimed at developing new technologies based on fast protons and ions, and simultaneously undertaking research into novel applications where proton or ion-based technologies provide a unique cutting edge. His current research explores nuclear microscopy in addition to the ion beam modification of materials – modifying optical, electrical, and magnetic properties of materials including bulk materials, semiconductors, non-linear optical materials and 2D materials. André Schleife is an Associate Professor at the University of Illinois Urbana-Champaign, United States. His research focus on computational material science and electronic and accelerated materials. He received the 2023 Dean’s Award for Excellence in Research. His group uses advanced computation to understand and predict this intricate interplay for materials in electronic and energy applications and under extreme conditions. They study electronic excitations, triggered by interaction with electromagnetic and particle radiation, and subsequent femto-second relaxation processes.