Field Simulation for Accelerator Magnets: Vol. 1: Theory of Fields and Magnetic Measurements / Vol. 2: Methods for Design and Optimization - Hardcover

Über die Autorin bzw. den Autor

Stephan Russenschuck is a Principle Applied Physicist in the Accelerator Technology (TE) Department of the European Organization for Nuclear Research, CERN, Geneva, Switzerland. He is the leader of the magnetic measurement section in the TE department and the chairman of the technical and doctoral student committee (TSC). He received the Dipl.-Ing and Dr.-Ing. degrees in electrical engineering in 1986 and 1990 both from the Technical University Darmstadt. In 2000 he was recognized as a University Lecturer (Habilitation) for Theory of Electromagnetic Fields at the University of Vienna, Austria.
 
His research interests are mathematical optimization and numerical field computation techniques in support of magnet design, magnetic measurements, and accelerator operation. Stephan Russenschuck is the author of the numerical field computation program ROXIE and the author of the book "Field computation for accelerator magnets" published by Wiley-VCH.

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A comprehensive reference to the theory and practice of accelerator-magnet design and measurement

Particle accelerators have many fundamental and applied research applications in physics, materials science, chemistry, and life science. To accelerate electrons or hadrons to the required energy, magnets of highly uniform fields are needed, whose design and optimization are some of the most critical aspects of accelerator construction.

Field Simulation for Accelerator Magnets is a comprehensive two-volume reference work on the electromagnetic design of iron- and coil-dominated accelerator magnets and methods of magnetic-field measurements. It provides project engineers and beam physicists with the necessary mathematical foundations for their work.

Students of electrical engineering and physics will likewise find much value in these volumes, as the challenges to be met for field quality, electrical integrity, and robustness of accelerator magnets require an in-depth knowledge of electromagnetism. Accelerator-magnet design provides an excellent opportunity to learn mathematical methods and numerical techniques that have wide-ranging applications in industry and science.

Readers of the two volumes of this work will find:

• Authorship by the leading expert on magnetic fields of accelerator magnets
• Detailed discussion of topics such as vector algebra and analysis, network theory, analytical and numerical field computation, magnetic measurements, elementary beam optics, and many more
• Application of mathematical optimization techniques, multiphysics simulation, and model-based systems engineering