Performance and simulation of a double-gap resistive plate chamber in the avalanche mode

Ahn Sung Hwan; Bahk, S Y; Hong Byung Sik; Hong Seong Jong; Ito, M; Kang, T I; Kim, B I; Kim, J H; Kim, Y J; Kim, Y U; Koo, D G; Lee Hyup Woo; Lee Kyong Sei; Lee Seok Jae; Lee, K B; Lim, J K; Moon, D H; Nam, S K; Park, S; Park, W J; Rhee June Tak; Ryu, M S; Sim Kwang Souk

Performance and simulation of a double-gap resistive plate chamber in the avalanche mode

Authors: Ahn Sung Hwan
S Y Bahk
Hong Byung Sik
Hong Seong Jong
M Ito
T I Kang
B I Kim
J H Kim
Y J Kim
Y U Kim
D G Koo
Lee Hyup Woo
Lee Kyong Sei
Lee Seok Jae
K B Lee
J K Lim
D H Moon
S K Nam
S Park
W J Park
Rhee June Tak
M S Ryu
Sim Kwang Souk
Publication date: 1 January 2004
Publisher

Abstract

We present a detailed analysis of the time and the charge signals of a prototype double-gap resistive plate chamber for the endcap region of the Compact Muon Solenoid (CMS) detector at the Large Hadron Collider (LHC). The chamber was built with relatively low-resistivity bakelite. The time and the charge results demonstrate that the high- voltage plateau, which satisfies various CMS requirements for the efficiency, the noise cluster rate, the fraction of the large signal, and the streamer probability, can be extended at least up to 400 V with the present design. In addition, a simple avalanche multiplication model is studied in detail. The model can reproduce the experimental charge spectra reasonably well. The charge information enables us to estimate the effective Townsend coefficient in avalanche-mode operation

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