Cryopumping and Vacuum Systems

TL;DR

This paper introduces the principles of cryogenic vacuum systems, focusing on cryopumping, surface interactions, and their application in large-scale cryogenic accelerators like the LHC.

Contribution

It provides a comprehensive overview of cryogenic vacuum science, including surface phenomena and system modeling, with practical insights from the LHC case study.

Findings

Cryopumping significantly increases molecule sojourn time at cryogenic temperatures.

Surface properties and roughness influence vacuum system performance.

Operational strategies for cryogenic beam vacuum systems are discussed.

Abstract

The understanding of complex and/or large vacuum systems operating at cryogenic temperatures requires a specific knowledge of the vacuum science at such temperatures. At room temperature, molecules with a low binding energy to a surface are not pumped. However, at cryogenic temperatures, their sojourn time is significantly increased, thanks to the temperature reduction, which allow a "cryopumping". This lecture gives an introduction to the field of cryogenic vacuum, discussing surface desorption, sticking probability, thermal transpiration, adsorption isotherms, vapour pressure of usual gases, industrial surfaces and roughness factors. These aspects are illustrated with the case of the Large Hardon Collider explaining its beam screen and its cryosorber, leaks and beam vacuum system modelling in a cryogenic environment. Finally, operation of cryogenic beam vacuum systems is discussed for LHC and other cryogenic machines.