Coulomb Interactions in Particle Beams

1st Edition, Volume 230 - October 10, 2024
Imprint: Academic Press
Author: Guus Jansen
Editors: Peter W. Hawkes, Martin Hÿtch
Language: English
Hardback ISBN:
9 7 8 - 0 - 4 4 3 - 2 9 7 8 4 - 7
eBook ISBN:
9 7 8 - 0 - 4 4 3 - 2 9 7 8 5 - 4

Coulomb Interactions in Particle Beams, Volume 230, the latest release in the Advances in Imaging and Electron Physics series, merges two long-running serials, Advances in E… Read more

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Coulomb Interactions in Particle Beams, Volume 230, the latest release in the Advances in Imaging and Electron Physics series, merges two long-running serials, Advances in Electronics and Electron Physics and Advances in Optical and Electron Microscopy. The series features articles on the physics of electron devices (especially semiconductor devices), particle optics at high and low energies, microlithography, image science, digital image processing, electromagnetic wave propagation, electron microscopy, and the computing methods used in all these domains.

Coulomb Interactions in Particle Beams
Cover image
Title page
Table of Contents
Series Page
Copyright
Preface
Chapter One Introduction
Abstract
Keywords
1.1 Introduction
1.2 Focused particle beam systems
1.3 Classification of interaction phenomena
1.4 Organization of the chapters
References☆
Chapter Two Historical notes
Abstract
Keywords
2.1 Introduction
2.2 Particle optics and particle interactions
2.3 Boersch effect
2.4 Trajectory displacement effect
2.5 Space charge effect in low density particle beams
2.6 Monte Carlo simulation
References☆
Chapter Three General beam properties
Abstract
Keywords
3.1 Introduction
3.2 Beam parameters
3.3 Classification of beams
3.4 Hamilton's formalism and Liouville's theorem
3.5 Boltzmann equation
3.6 Conservation of beam emittance and brightness
3.7 Beam temperature
3.8 Thermodynamic limits for particle interaction effects
3.9 Debeye screening
3.10 Potential energy relaxation
References☆
Chapter Four The many body problem of particles interacting through an Inverse Square force law
Abstract
Keywords
4.1 Introduction
4.2 Vlasov equation
4.3 Fokker–Planck equation
4.4 Aspects of the diffusion approximation
4.5 Calculation of coefficients of dynamical friction and diffusion
4.6 Coulomb logarithm
4.7 Discussion of the Fokker–Planck approach
4.8 Validity of the Fokker–Planck approach for particle beams
4.9 Holtsmark distribution
4.10 Conclusions
References☆
Chapter Five Concepts of an analytical model for statistical interactions in particle beams
Abstract
Keywords
5.1 Introduction
5.2 General formulation of the problem
5.3 Reduction of the N-particle problem
5.3.1 First order perturbation approximation
5.3.2 Closest encounter approximation
5.3.3 Extended two-particle approximation
5.3.4 Mean square field fluctuation approximation
5.4 Calculation of the displacement distribution
5.5 Moments and cumulants of the displacement distribution
5.6 On- and off-axis reference trajectories
5.7 Models in one, two, and three dimensions
5.8 Distribution of the interaction force in cylindrical beams
5.9 Representation in the k-domain
5.10 Addition of the effects generated in individual beam segments
5.11 Slice method
References☆
Chapter Six Two-particle dynamics
Abstract
Keywords
6.1 Introduction
6.2 Basic properties
6.3 Coordinate representation in the orbital plane
6.4 Dynamics of a complete collision
6.5 General analysis of the two-particle dynamical problem
6.6 Numerical approach to the dynamical problem
6.7 Dynamics of a nearly complete collision
6.8 First order perturbation dynamics
6.9 Collisions with zero initial relative velocity
6.10 Expressions for the longitudinal velocity shift Δvz
6.11 Expressions for the transverse velocity shift Δv⊥
6.12 Expressions for the spatial shift Δr
6.13 Coulomb scaling
Appendix 6.A. Mathematics of nearly complete collision dynamics
References☆
Chapter Seven Boersch effect
Abstract
Keywords
7.1 Introduction
7.2 General aspects
7.3 Beam segment with a narrow crossover
7.4 Homocentric cylindrical beam segment
7.5 Beam segment with a crossover of arbitrary dimensions
7.6 Results for Gaussian angular and spatial distributions
7.7 Thermodynamic limits
Chapter Eight Statistical angular deflections
Abstract
Keywords
8.1 Introduction
8.2 General aspects
8.3 Beam segment with a narrow crossover
8.4 Homocentric cylindrical beam segment
8.5 Beam segment with a crossover of arbitrary dimensions
8.6 Application of the slice method
8.7 Results for Gaussian angular and spatial distributions
Chapter Nine Trajectory displacement effect
Abstract
Keywords
9.1 Introduction
9.2 General aspects
9.3 Homocentric beam segment with a crossover
9.4 Homocentric cylindrical beam segment
9.5 Beam segment with a crossover of arbitrary dimensions
9.6 Trajectory displacement and angular deflection distribution
9.7 Results for Gaussian angular and spatial distributions
References☆
Chapter Ten Further investigations on statistical interactions
Abstract
Keywords
10.1 Introduction
10.2 Exact approach for off-axis reference trajectories
10.3 Approximating approach for off-axis reference trajectories
10.4 Nonmonochromatic beams
10.5 Beams in an external uniform axial electrostatic field
10.6 Relativistic beams
Appendix 10.A. Distributions for the average reference trajectory
References☆
Chapter Eleven Space charge effect in low density particle beams
Abstract
Keywords
11.1 Introduction
11.2 General aspects
11.3 Beams with laminar flow
11.4 First order perturbation theory
11.5 First order optical properties of the space charge lens
11.6 Third order geometrical aberrations of the space charge lens
11.7 Beam segment with a narrow crossover
11.8 Homocentric cylindrical beam segment
11.9 Addition of the effects generated in individual beam segments
References☆
Chapter Twelve Calculation of different spot- and edge-width measures
Abstract
Keywords
12.1 Introduction
12.2 Spot-width obtained by knife-edge scans
12.3 Edge-width of a shaped spot
12.4 Trajectory displacement effect
12.5 Chromatic aberration
12.6 Spherical aberration
12.7 Space charge effect
12.8 Results for a truncated Gaussian angular distribution
References☆
Chapter Thirteen Monte Carlo simulation of particle beams
Abstract
Keywords
13.1 Introduction
13.2 Source routine
13.3 Optical elements
13.4 Numerical ray tracing
13.5 Analytical ray tracing
13.6 Simulation of large currents near the source
13.7 Correction of finite-size effects
13.8 Data analysis
13.9 Accuracy limitations of the MC program
13.10 MC simulation vs analytical modeling
13.11 Program organization and examples
Appendix 13. A. Random number routine
Appendix 13. B. Polynomial fit algorithm
References☆
Chapter Fourteen Comparison of analytical theory with Monte Carlo simulations
Abstract
Keywords
14.1 Introduction
14.2 General aspects
14.3 Voltage and current dependencies for a fixed geometry
14.4 Geometry and current dependencies for a fixed beam voltage
14.5 Discussion of the results
References☆
Chapter Fifteen Comparison of recent theories on statistical interactions
Abstract
Keywords
15.1 Introduction
15.2 Boersch effect
15.2.1 Zimmermann and Knauer
15.2.2 Loeffler
15.2.3 Crewe
15.2.4 Rose and Spehr
15.2.5 De Chambost and Hennion
15.2.6 Sasaki
15.2.7 Massey, Jones and Plummer
15.2.8 Comparison of theories for a beam segment with a crossover
15.3 Statistical angular deflections
15.3.1 Loeffler and Hudgin
15.3.2 Weidenhausen, Spehr and Rose
15.3.3 Massey, Jones and Plummer
15.3.4 Comparison of theories for a beam segment with a crossover
15.4 Trajectory displacement effect
15.4.1 Loeffler and Hudgin
15.4.2 De Chambost
15.4.3 Spehr
15.4.4 Comparison of theories
15.5 Conclusions
References☆
Chapter Sixteen Summary for the one-minute designer
Abstract
Keywords
16.1 Introduction
16.2 Physical aspects
16.3 Parameter dependencies
16.4 Equations for the Boersch effect
16.5 Equations for the trajectory displacement effect
16.6 Equations for the space charge effect
16.7 Addition of the effects generated in individual beam segments
References☆
References
Index

Peter W. Hawkes

Peter Hawkes obtained his M.A. and Ph.D (and later, Sc.D.) from the University of Cambridge, where he subsequently held Fellowships of Peterhouse and of Churchill College. From 1959 – 1975, he worked in the electron microscope section of the Cavendish Laboratory in Cambridge, after which he joined the CNRS Laboratory of Electron Optics in Toulouse, of which he was Director in 1987. He was Founder-President of the European Microscopy Society and is a Fellow of the Microscopy and Optical Societies of America. He is a member of the editorial boards of several microscopy journals and serial editor of Advances in Electron Optics.

Affiliations and expertise

Founder-President of the European Microscopy Society and Fellow, Microscopy and Optical Societies of America; member of the editorial boards of several microscopy journals and Serial Editor, Advances in Electron Optics, France

Martin Hÿtch

Dr Martin Hÿtch, serial editor for the book series “Advances in Imaging and Electron Physics (AIEP)”, is a senior scientist at the French National Centre for Research (CNRS) in Toulouse. He moved to France after receiving his PhD from the University of Cambridge in 1991 on “Quantitative high-resolution transmission electron microscopy (HRTEM)”, joining the CNRS in Paris as permanent staff member in 1995. His research focuses on the development of quantitative electron microscopy techniques for materials science applications. He is notably the inventor of Geometric Phase Analysis (GPA) and Dark-Field Electron Holography (DFEH), two techniques for the measurement of strain at the nanoscale. Since moving to the CEMES-CNRS in Toulouse in 2004, he has been working on aberration-corrected HRTEM and electron holography for the study of electronic devices, nanocrystals and ferroelectrics. He was laureate of the prestigious European Microscopy Award for Physical Sciences of the European Microscopy Society in 2008. To date he has published 130 papers in international journals, filed 6 patents and has given over 70 invited talks at international conferences and workshops.

Affiliations and expertise

Senior Scientist, French National Centre for Research (CNRS), Toulouse, France

Guus Jansen

Guus Jansen earned both his MSc (1983) and PhD (1988) in Physics from Delft University of Technology, graduating Cum Laude for both degrees. His PhD thesis on "Coulomb Interactions in Particle Beams" won the prestigious Shell Award for the best research project at Delft in 1988. This work was first published by Academic Press in 1990 in the series Advances in Electronics and Electron Physics and is being republished in 2024 in Advances in Electronics and Imaging Physics.

From 1983 to 1985, his first role after earning his MSc was as a postdoctoral researcher at IBM's General Technology Division in New York, focusing on variable-shaped beam electron lithography. After his PhD, he served as a research physicist at the Royal Dutch/Shell Laboratories in Amsterdam (1989–1992), where he led the development and modeling of refinery equipment and chemical processes.

In 1992, he transitioned into strategic consulting as a Senior Management Consultant at Monitor Company (1992–1996), advising top-tier corporations across a range of industries. In 1996, he joined Telfort, a joint venture between British Telecom and Dutch Railways (NS), as Director of Marketing & Business Development. As a member of the board, he oversaw corporate strategy, business planning and development, product development, and management.

Since 2000, Guus has operated as a serial entrepreneur through Caneval Ventures, his business development and investment company. Caneval Ventures has initiated, supported, and led multiple startups and scale-ups in the ICT and renewable energy sectors, with Guus serving as CEO, CCO, and CFO of various companies.

In 2002, Caneval Ventures acquired the IP rights for MonTec and Interac software, both of which were initially developed as part of Guus' PhD research. These software packages have been adopted by leading companies like IBM, Toshiba, Philips, and several universities and research institutions globally. Over the years, Caneval Ventures has provided consultancy to various institutions and companies, specializing in quantifying and mitigating the effects of Coulomb interactions in charged particle systems.

Affiliations and expertise

Caneval Ventures, The Netherlands

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Coulomb Interactions in Particle Beams

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Peter W. Hawkes

Martin Hÿtch

Guus Jansen

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