The second edition of the book addresses numerous typographical errors and inaccuracies identified by readers and contributors over the past decade. In addition, the authors have expanded and updated several chapters, revised the reference list as needed, and introduced new chapters that extend the analysis of complex topics such as intrabeam scattering (IBS). The edition also offers new insights into key subjects, including strong hadron cooling, luminosity limits in current and near-future hadron and leptonhadron colliders, and the energyluminosity trade-offs of ultimate colliders.
This book explores advancements in accelerator physics and technology implemented at the Tevatron protonantiproton collider, which remained the worlds most powerful accelerator for nearly two decades before the completion of the Large Hadron Collider.
Covering the history of collider operation and upgrades, the book delves into innovative beam optics designs, orbit control techniques, antiproton production and cooling, beam instabilities and feedback systems, halo collimation strategies, and state-of-the-art beam instrumentation. Through these discussions, the book highlights the complexity and breadth of challenges associated with modern hadron accelerators while offering a systematic approach essential for designing and constructing next-generation colliders.
A valuable resource for researchers in high-energy physics, this book also serves as an excellent introduction for students studying beam physics in colliders.
Introduction.- Beam Optics and Orbits: Methods Used at the Tevatron
Accelerators.- Magnets and Magnetic Field Effects.- Longitudinal Beam
Manipulations.- Collective Instabilities in the Tevatron Collider Run II
Accelerators.- Emittance Growth and Beam Loss.- Antiproton Production and
Cooling.- Beam Beam Effects.- Beam Instrumentation.- Cooling of Dense Proton
Bunches.- Tevatron, LHC Whats Next? On the Feasibility and Limits of Energy
Frontier Colliders.
Dr. Sci. (Habil.) Valery Lebedev is an accelerator physicist known for his contributions to beam dynamics and the design and optimization of high-energy particle accelerators. As a Distinguished Scientist at Fermilab, he played a leading role in the development of advanced accelerator concepts, including the Tevatron and PIP-II. His work spans nonlinear beam dynamics, collective effects, and high-intensity beam physics. He is a Fellow of the American Physical Society and the recipient of the 2023 Dieter Möhl Award for lifetime achievements and important contributions to the field of beam cooling and its applications. He has authored numerous publications in accelerator science.
Dr. Prof. Vladimir Shiltsev is a leading accelerator physicist whose work has advanced the design and operation of high-energy particle accelerators. As a Distinguished Scientist at Fermilab, he played key roles in the Tevatron collider program, developing novel techniques for beam control and luminosity optimization. His research spans beam dynamics, accelerator technologies, and future collider concepts. He has authored and edited numerous books and articles on accelerator physics as well as on the history of science. He is a Fellow of the American Physical Society, the Institute of Electrical and Electronics Engineers, and the American Association for the Advancement of Science; a corresponding foreign member of the Bologna Academy of Sciences; and a member of Academia Europaea. He has received several awards for his contributions to the field.
