Influence of nanoparticulates and microgrooves on the secondary electron yield and electrical resistance of laser-treated copper surfaces

Patrick Krkotić (Lead / Corresponding author), Tamás Győző Madarász, Catarina Serafim, Holger Neupert, Ana Teresa Perez Fontenla, Marcel Himmerlich, Sergio Calatroni (Lead / Corresponding author), Stefan Wackerow, Amin Abdolvand

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Abstract

Laser surface structuring has proven to be an effective technique for achieving a copper surface with secondary electron yield (SEY) values close to or below unity. However, the attributes that minimize SEY, such as moderately deep grooves and redeposited nanoparticles, may lead to undesirable consequences, including increased radio frequency surface resistance. This investigation systematically examined data about different cleaning procedures designed to eliminate redeposited adsorbed particulates. Various analysis techniques were used iteratively after each consecutive cleaning step, providing insights into the evolving surface characteristics. The collected experimental results identified distinct impacts of microgrooves, groove orientation, and associated particulates on secondary electron yield and surface resistance. Exposing the crests while retaining high particulate coverage in the grooves leads to reduced SEY values and surface resistance, suggesting that the tips of the grooves exert a more significant influence on surface current density than the groove depth. At the same time, nanoparticles in the grooves have a more significant impact on SEY values than the exposed tips at the surface.
Original languageEnglish
Article number113101
Number of pages11
JournalPhysical Review Accelerators and Beam
Volume27
DOIs
Publication statusPublished - 26 Nov 2024

Keywords

  • Electrical properties
  • Roughness
  • Vacuum technology
  • Hadron colliders
  • Laser ablation
  • Laser techniques

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