학술논문
Minimizing plasma temperature for antimatter mixing experiments
Document Type
article
Author
Hunter E.D.; Amsler C.; Breuker H.; Chesnevskaya S.; Costantini G.; Ferragut R.; Giammarchi M.; Gligorova A.; Gosta G.; Higaki H.; Kanai Y.; Killian C.; Kletzl V.; Kraxberger V.; Kuroda N.; Lanz A.; Leali M.; Mäckel V.; Maero G.; Malbrunot C.; Mascagna V.; Matsuda Y.; Migliorati S.; Murtagh D.J.; Nagata Y.; Nanda A.; Nowak L.; Pasino E.; Romé M.; Simon M.C.; Tajima M.; Toso V.; Ulmer S.; Uggerhøj U.; Venturelli L.; Weiser A.; Widmann E.; Wolz T.; Yamazaki Y.; Zmeskal J.
Source
EPJ Web of Conferences, Vol 262, p 01007 (2022)
Subject
Language
English
ISSN
2100-014X
Abstract
The ASACUSA collaboration produces a beam of antihydrogen atoms by mixing pure positron and antiproton plasmas in a strong magnetic field with a double cusp geometry. The positrons cool via cyclotron radiation inside the cryogenic trap. Low positron temperature is essential for increasing the fraction of antihydrogen atoms which reach the ground state prior to exiting the trap. Many experimental groups observe that such plasmas reach equilibrium at a temperature well above the temperature of the surrounding electrodes. This problem is typically attributed to electronic noise and plasma expansion, which heat the plasma. The present work reports anomalous heating far beyond what can be attributed to those two sources. The heating seems to be a result of the axially open trap geometry, which couples the plasma to the external (300 K) environment via microwave radiation.