Overview

Choice Recommended Title, January 2020 Providing a vital resource in tune with the massive advancements in accelerator technologies that have taken place over the past 50 years, Accelerator Radiation Physics for Personnel and Environmental Protection is a comprehensive reference for accelerator designers, operators, managers, health and safety staff, and governmental regulators. Up-to-date with the latest developments in the field, it allows readers to effectively work together to ensure radiation safety for workers, to protect the environment, and adhere to all applicable standards and regulations. This book will also be of interest to graduate and advanced undergraduate students in physics and engineering who are studying accelerator physics. Features: Explores accelerator radiation physics and the latest results and research in a comprehensive single volume, fulfilling a need in the market for an up-to-date book on this topic Contains problems designed to enhance learning Addresses undergraduates with a background in math and/or science

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9781138589018

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Reviews

This book has its origins in a graduate course first taught at the US Particle Accelerator School in 1993. The objective of the course and of the book is to address the major radiation physics issues that are relevant to the wide spectrum of particle accelerators in use across the world today. To attain this goal, Cossairt and Quinn (both, Fermi National Accelerator Lab) first develop the mathematical and physical techniques and concepts associated with modern particle accelerators, covered in chapters 1 and 2. Altogether, the authors have attained their stated objective of providing a comprehensive reference for accelerator designers, operators, managers, health and safety staff, and governmental regulators. The major topics dealt with in detail are prompt radiation fields due to electrons (chapter 3), prompt radiation fields due to protons and ions (chapter 4), unique low-energy radiation phenomena (chapter 5), shielding materials and neutron energy spectra (chapter 6), and induced radioactivity in accelerator components and environmental media (chapters 7 and 8). The ninth and final chapter is particularly useful, covering radiation protection instrumentation at accelerators. This textbook is mainly written for people whose work will involve particle accelerators. - A. M. Strauss, Vanderbilt University, in CHOICE, January 2020 Don Cossairt and Matthew Quinn's recently published book summarises both basic concepts of the propagation of particles through matter and fundamental aspects of protecting personnel and environments against prompt radiation and radioactivity. It constitutes a compact and comprehensive compendium for radiation-protection professionals working at accelerators. The book's content originates in a course taught by Cossairt, a longstanding and recently retired radiation expert at Fermi lab, at numerous sessions of the US Particle Accelerator School (USPAS) since the early 1990s. It is also available as a Fermilab report, which has stood the test of time as one of the standard health-physics handbooks for accelerator facilities for more than 20 years. Quinn, the book's co-author, is the laboratory's radiation-physics department manager. The book begins with a short overview of the physical and radiological quantities relevant for radiation-protection assessments, and briefly sketches the mechanisms for energy loss and scattering during particle transport in matter. The introductory part concludes with chapters on the Boltzmann equation, which in this context describes the transport of particles through matter, and its solution using Monte Carlo methods. The following chapters illustrate the radiation fields that are induced by the interactions of electron, hadron and ion beams with beamline components. The tools described in these chapters are parametrised equations and handy rules-of-thumb. Graphs of representative particle spectra and yields serve for back-of-the-envelope calculations and describe the fundamental characteristics of radiation fields. The second half of the book deals with the practical questions encountered in everyday radiation-protection assessments, such as the selection of the most efficient shielding material for a given radiation field, the energy spectra to be expected outside of the shielding, where personnel might be present, and lists of the radiologically relevant nuclides that are typically produced around accelerators. It also provides a compact introduction to activation at accelerators. The final chapter gives a comprehensive overview of the radiation-protection instrumentation traditionally used at accelerators, helping the reader to select the most appropriate detector for a given radiation field. Some topics have evolved since the time when the material upon which the book is based was written. For example, the rules-of-thumb presented in the text are nowadays mostly used for cross-checking results obtained with much more powerful and user-friendly Monte Carlo transport programs. The book gives many tools necessary for obtaining rough but valuable estimates for setting up simulations and crosschecking results. -Stefan Roesler, CERN, in CERN Courier, Vol 60 No.5 (September/October 2020)

This book has its origins in a graduate course first taught at the US Particle Accelerator School in 1993. The objective of the course and of the book is to address the major radiation physics issues that are relevant to the wide spectrum of particle accelerators in use across the world today. To attain this goal, Cossairt and Quinn (both, Fermi National Accelerator Lab) first develop the mathematical and physical techniques and concepts associated with modern particle accelerators, covered in chapters 1 and 2. Altogether, the authors have attained their stated objective of providing a comprehensive reference for accelerator designers, operators, managers, health and safety staff, and governmental regulators. The major topics dealt with in detail are prompt radiation fields due to electrons (chapter 3), prompt radiation fields due to protons and ions (chapter 4), unique low-energy radiation phenomena (chapter 5), shielding materials and neutron energy spectra (chapter 6), and induced radioactivity in accelerator components and environmental media (chapters 7 and 8). The ninth and final chapter is particularly useful, covering radiation protection instrumentation at accelerators. This textbook is mainly written for people whose work will involve particle accelerators. - A. M. Strauss, Vanderbilt University, in CHOICE, January 2020

The book begins with a nice review of basic concepts in both radiation safety and accelerator physics that ranges from tracing the evolution of radiation safety standards through how radiation fields are produced around accelerators to how beams of charged particles are magnetically focused. After dispensing with the basics, the book goes on to discuss prompt radiation fields from electrons and from protons and ions, and it includes a chapter on phenomena that are unique to low-energy radiation... Of particular interest, however, were the chapters about induced radioactivity... Rounding out this book are chapters on radiation shielding and radiation protection instrumentation... The book itself (including the electronic version) is well done. The graphics are crisp, text (even smaller fonts) is easy to read, and the book just looks good. Each section includes not only a written description of the subject that delves fairly deeply into the physics underlying even the seemingly mundane aspects of work at these facilities. This is accompanied by a mathematical description as well... In addition, each section includes a question set with questions of varying complexity and difficulty. In fact, I should have mentioned earlier that this is not only a great reference book but is also the first new graduate-level textbook on this topic since the classic tome by Patterson and Thomas, published in 1973. - P. Andrew Karam in Health Physics Journal (vol 121, 2021).

Author Information

J. Donald Cossairt is a Distinguished Scientist at the Fermi National Accelerator Laboratory (Fermilab) in Batavia, Illinois. He received a BA in physics and mathematics from Indiana Central College (now the University of Indianapolis) (1970) and MS and PhD degrees in experimental nuclear physics from Indiana University Bloomington (1972, 1975). His career began with a postdoctoral appointment in nuclear physics research at the Texas A&M University Cyclotron Institute, then transitioned to radiation physics with his move to Fermilab in 1978. He is a member of the American Physical Society, a Fellow Member of the Health Physics Society, a Distinguished Emeritus Member of the National Council on Radiation Protection and Measurements and is a Certified Health Physicist. Dr. Cossairt has numerous publications in health physics, nuclear physics, and particle physics. He received a G. William Morgan Lectureship Award from HPS in 2011. He has been an instructor of the Radiation Physics, Regulation and Management course at 14 sessions the U.S. Particle Accelerator School and was co-academic dean of the Professional Development School of the Health Physics Society held in Oakland, California in 2008. Matthew Quinn is the Senior Radiation Safety Officer and Laser Safety Officer at the Fermi National Accelerator Laboratory (Fermilab) in Batavia, Illinois.  He has worked on shielding assessments, operational radiation safety, radioanalytical measurements and laser safety.  Dr. Quinn is a three-time instructor of the Radiation Physics, Regulation and Management course at the U.S. Particle Accelerator School, serves as the Vice Chair of the Department of Energy EFCOG Laser Safety Task Group, and is the president-elect of the Accelerator Section of the Health Physics Society.  He received a BS in physics from Loyola University Chicago (2000), MS and PhD degrees in nuclear physics from the University of Notre Dame (2005, 2009), and was a postdoctoral researcher in the Department of Radiation Oncology at Loyola University Medical Center before joining Fermilab in 2010. 

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