Speaker
Description
High-intensity hadron linacs stand at the forefront of accelerator science, delivering the beam brilliance required by spallation sources, neutrino factories, and future colliders. Yet the same space-charge forces that enable high current and brightness can degrade beam quality, drive instabilities, and impose stringent intensity limits. This lecture offers a concise roadmap for understanding—and ultimately mitigating—these constraints.
After a brief physical motivation, we develop the theory from first principles. Starting with Maxwell’s equations in the beam rest frame, we derive the self-consistent Poisson–Vlasov system and recover the classical four-dimensional Kapchinskij–Vladimirskij (KV) solution. Step by step, participants trace how the KV distribution leads to the envelope equations and to practical metrics such as tune depression.
We then move beyond this ideal model to realistic beam distributions, examining both analytical treatments and numerical approaches, notably particle-in-cell (PIC) simulations. Numerical integration techniques will be explored further in a companion lecture—“Numerical Methods in High-Intensity Linacs”—which delves into solving the complex collective dynamics, such as space-charge forces, encountered in modern accelerators.
