Speaker
Description
Building upon the theoretical foundations introduced in the previous lecture, this second lecture on Wakefields and Impedances focuses on applications, practical examples, and their impact on modern accelerator design and operation. The role of impedance studies in contemporary machines is discussed, highlighting how beam coupling impedance has become a central ingredient in performance optimization, intensity upgrades, and reliability of working accelerators.
Representative examples of impedance contributions are presented, illustrating how seemingly small and distributed sources can collectively determine machine limitations. The complementary roles of analytical, numerical, and experimental approaches are examined. Analytical models remain essential for understanding scaling laws and for estimating the cumulative effect of numerous small discontinuities. Numerical simulations enable accurate treatment of complex geometries and realistic structures, while experimental techniques provide validation and benchmarking of impedance models.
Wakefield effects in linear accelerators are discussed separately, emphasizing differences with respect to circular machines and the implications for beam quality and stability.
Beyond their potentially detrimental impact, wakefields can also be exploited constructively. The lecture briefly explores scenarios where wakefields are beneficial, including wakefield-based devices, and advanced acceleration concepts beyond plasma-based schemes.
The concept of a comprehensive machine impedance model is introduced as a practical tool for design and operation. Examples are drawn from the LHC impedance model, operational experience and mitigation strategies in existing machines, and perspectives for future colliders and light sources. The lecture concludes by connecting impedance control, higher-order mode damping strategies, and advanced accelerator concepts within a unified framework of beam–structure interaction.