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The first half deals with the motion of a single particle under the influence of electronic and magnetic fields. The basic language of linear and circular accelerators is developed. The principle of phase stability is introduced along with phase oscillations in linear accelerators and synchrotrons. Presents a treatment of betatron oscillations followed by an excursion into nonlinear dynamics and its application to accelerators. The second half discusses intensity dependent effects, particularly space charge and coherent instabilities. Includes tables of parameters for a selection of accelerators which are used in the numerous problems provided at the end of each chapter.
The must – read guidebook for entrepreneurs looking to get into accelerator programs and to build and scale their startups with speed Accelerator programs have become one of the most powerful and valuable resources for entrepreneurs seeking to learn rapidly, build powerful networks, raise capital, build their startups and do this at speed and scale. In recent years, the number of accelerator programs around the world has grown at an incredible rate, propelling startups such as AirBnB, Uber, DropBox, Reddit, and others — many to billion-dollar valuations. The number of accelerators, the differences in accelerator program offerings and the unique benefits and costs of different accelerator locations makes choosing the right accelerator a challenge. Selecting the wrong accelerator, failing to be accepted in the right one, or not fully taking advantage of all the accelerator has to offer can be costly, sometimes fatal. With the stakes so high, entrepreneurs need to understand all their options, choose carefully and do the right things to maximize their chances of success. Startup Accelerators is the go to guide for any entrepreneur, providing a firsthand look into the acceptance criteria and inner workings of different accelerator programs. Written by entrepreneurs for entrepreneurs, this indispensable resource explains what different accelerator programs offer, how to get accepted, what to do during the program, how to raise money during accelerators, what to do after the program ends, and much more. Packed with real-world case studies and advice from leading experts on startup accelerator programs, this one-stop resource provides step-by-step guidance on the entire accelerator process. Reveals how accelerators help founders navigate different challenges in the startup journey Describes the differences in the benefits and costs of different accelerator programs Explains how to prepare accelerator applications Discloses what actions to take during an accelerator to make the most of it Depicts case studies of entrepreneurs’ accelerator applications, experiences and outcomes across different accelerators Features interviews with accelerator program managers, founders who went through accelerators, and investors in companies going through or having gone through accelerators Includes insightful data and reflections from entrepreneurship education researchers and academics Startup Accelerators: A Field Guide will prove to be invaluable for startup founders considering or going through accelerators, as well as aspiring entrepreneurs, educators, and other startup accelerator stakeholders.
The must – read guidebook for entrepreneurs looking to get into accelerator programs and to build and scale their startups with speed Accelerator programs have become one of the most powerful and valuable resources for entrepreneurs seeking to learn rapidly, build powerful networks, raise capital, build their startups and do this at speed and scale. In recent years, the number of accelerator programs around the world has grown at an incredible rate, propelling startups such as AirBnB, Uber, DropBox, Reddit, and others — many to billion-dollar valuations. The number of accelerators, the differences in accelerator program offerings and the unique benefits and costs of different accelerator locations makes choosing the right accelerator a challenge. Selecting the wrong accelerator, failing to be accepted in the right one, or not fully taking advantage of all the accelerator has to offer can be costly, sometimes fatal. With the stakes so high, entrepreneurs need to understand all their options, choose carefully and do the right things to maximize their chances of success. Startup Accelerators is the go to guide for any entrepreneur, providing a firsthand look into the acceptance criteria and inner workings of different accelerator programs. Written by entrepreneurs for entrepreneurs, this indispensable resource explains what different accelerator programs offer, how to get accepted, what to do during the program, how to raise money during accelerators, what to do after the program ends, and much more. Packed with real-world case studies and advice from leading experts on startup accelerator programs, this one-stop resource provides step-by-step guidance on the entire accelerator process. Reveals how accelerators help founders navigate different challenges in the startup journey Describes the differences in the benefits and costs of different accelerator programs Explains how to prepare accelerator applications Discloses what actions to take during an accelerator to make the most of it Depicts case studies of entrepreneurs’ accelerator applications, experiences and outcomes across different accelerators Features interviews with accelerator program managers, founders who went through accelerators, and investors in companies going through or having gone through accelerators Includes insightful data and reflections from entrepreneurship education researchers and academics Startup Accelerators: A Field Guide will prove to be invaluable for startup founders considering or going through accelerators, as well as aspiring entrepreneurs, educators, and other startup accelerator stakeholders.
This book provides systematic coverage of the beam-based techniques that accelerator physicists use to improve the performance of large particle accelerators, including synchrotrons and linacs. It begins by discussing the basic principles of accelerators, before exploring the various error sources in accelerators and their impact on the machine's performances. The book then demonstrates the latest developments of beam-based correction techniques that can be used to address such errors and covers the new and expanding area of beam-based optimization. This book is an ideal, accessible reference book for physicists working on accelerator design and operation, and for postgraduate studying accelerator physics. Features: Entirely self-contained, exploring the theoretic background, including algorithm descriptions, and providing application guidance Accompanied by source codes of the main algorithms and sample codes online Uses real-life accelerator problems to illustrate principles, enabling readers to apply techniques to their own problems Xiaobiao Huang is an accelerator physicist at the SLAC National Accelerator Laboratory at Stanford University, USA. He graduated from Tsinghua University with a Bachelor of Science in Physics and a Bachelor of Engineering in Computer Science in 1999. He earned a PhD in Accelerator Physics from Indiana University, Bloomington, Indiana, USA, in 2005. He spent three years on thesis research work at Fermi National Accelerator Laboratory from 2003-2005. He has worked at SLAC as a staff scientist since 2006. He became Accelerator Physics Group Leader of the SPEAR3 Division, Accelerator Directorate in 2015. His research work in accelerator physics ranges from beam dynamics, accelerator design, and accelerator modelling and simulation to beam based measurements, accelerator control, and accelerator optimization. He has taught several courses at US Particle Accelerator School (USPAS), including Beam Based Diagnostics, Accelerator Physics, Advanced Accelerator Physics, and Special Topics in Accelerator Physics.
This book explores the physics, technology and applications of particle accelerators. It illustrates the interconnections between applications and basic physical principles, enabling readers to better understand current and upcoming technologies and see beyond the paradigmatic borders of the individual fields. The reader will discover why accelerators are no longer just toys for scientists, but have also become modern and efficient nuclear workhorses. The book starts with an introduction to the relevant technologies and radiation safety aspects of accelerating electrons and ions from several keV to roughly 250 MeV. It subsequently describes the physics behind the interactions of these particle beams with matter. Mathematical descriptions and state-of-the-art computer models of energy-loss and nuclear interactions between the particle beams and targets round out the physics coverage. On this basis, the book then presents the most important accelerator applications in science, medicine, and industry, explaining and comparing more than 20 major application fields, encompassing semiconductors, cancer treatment, and space exploration. Despite the disparate fields involved, this book demonstrates how the same essential technology and physics connects all of these applications.
This unique resource offers you a clear overview of medical and industrial accelerators. Using minimal mathematics, this book focuses on offering thorough explanations of basic concepts surrounding the operation of accelerators. You find well illustrated discussions designed to help you use accelerator-based systems in a safer, more productive, and more reliable manner. This practical book details the manufacturing process for producing accelerators for medical and industrial applications. You become knowledgeable about the commonly encountered real-world manufacturing issues and potential sources of defects which help you avoid costly production problems. From principles of operation and the role of accelerators in cancer radiation therapy, to manufacturing techniques and future trends in accelerator design and applications, this easy-to-comprehend volume quickly brings you up-to-speed with the critical concepts you need to understand for your work in the field.
This book by Helmut Wiedemann is a well-established, classic text, providing an in-depth and comprehensive introduction to the field of high-energy particle acceleration and beam dynamics. The present 4th edition has been significantly revised, updated and expanded. The newly conceived Part I is an elementary introduction to the subject matter for undergraduate students. Part II gathers the basic tools in preparation of a more advanced treatment, summarizing the essentials of electrostatics and electrodynamics as well as of particle dynamics in electromagnetic fields. Part III is an extensive primer in beam dynamics, followed, in Part IV, by an introduction and description of the main beam parameters and including a new chapter on beam emittance and lattice design. Part V is devoted to the treatment of perturbations in beam dynamics. Part VI then discusses the details of charged particle acceleration. Parts VII and VIII introduce the more advanced topics of coupled beam dynamics and describe very intense beams – a number of additional beam instabilities are introduced and reviewed in this new edition. Part IX is an exhaustive treatment of radiation from accelerated charges and introduces important sources of coherent radiation such as synchrotrons and free-electron lasers. The appendices at the end of the book gather useful mathematical and physical formulae, parameters and units. Solutions to many end-of-chapter problems are given. This textbook is suitable for an intensive two-semester course starting at the senior undergraduate level.
Low Energy Particle Accelerator-Based Technologies and Their Applications describes types of low energy accelerators, presents some of the main manufacturers, illustrates some of the accelerator laboratories around the globe and shows examples of successful transfers of accelerators to needed laboratories. Key Features: Presents new trends and the state of the art in a field that's growing Provides an overview of numerous applications of such accelerators in medicine, industry, earth sciences, nuclear non-proliferation and oil Fills a gap, with the author drawing on his own experiences with transporting such relatively large machines from one lab to the other that require a tremendous amount of planning, technical and engineering efforts This is an essential reference for advanced students as well as for physicists, engineers and practitioners in accelerator science. About the Author Dr. Vladivoj (Vlado) Valković, a retired professor of physics, is a fellow of the American Physical Society and Institute of Physics (London). He has authored 22 books (from Trace Elements, Taylor & Francis, 1975, to Radioactivity in the Environment, Elsevier, 1st Edition 2001, 2nd Edition 2019), and more than 400 scientific and technical papers in the research areas of nuclear physics, applications of nuclear techniques to trace element analysis in biology, medicine and environmental research. He has lifelong experience in the study of nuclear reactions induced by 14 MeV neutrons. This research has been done through coordination and works on many national and international projects, including US-Croatia bilateral, NATO, IAEA, EU-FP5, FP6 and FP7 projects. Cover photo credit: 3SDH 1 MV Pelletron system with RF source and analysis endstation designed with the intended purpose of aiding in fusion research. It is capable of Ion Beam Analysis (IBA) techniques such as RBS, ERD, PIXE and NRA. Further detectors could be added to the endstation to allow for other techniques. Installed in Japan in 2014. Courtesy of National Electrostatics Corp.
Considers authorization of funds for an AEC linear electron accelerator to be located at Stanford Univ. Appendixes include. a. "Proposal for a Two-Mile Linear Electron Accelerator," by Stanford Univ, Apr. 1957 (p. 283-426). b. "Review of the Stanford Proposal for a Two-Mile Linear Electron Accelerator," by William M. Brobeck P Assocs, June 1958 (p. 427-525). c. "Site Feasibility of Stanford's Proposed Two-Mile Linear Electron Accelerator," by Frank W. Atchley and Robert O. Dobbs, July 1959 (p. 577-649).