Simulation studies of Micromegas and parallel ionization multiplier with woven mesh

We report simulation results of the Micromegas in a bulk and PIM (parallel ionization multiplier) with one or more layers of woven micromeshes based on 3D models and Garfield/ Magboltz. Studies are conducted for different detector geometries. Effects of wire diameter, mesh pitch, mesh effective thickness and gas mixture are investigated. The transverse diffusion of drifting electrons and broadening of electron clouds that affect electron transfer through the micromeshes are studied. Different arrangements of gas gains in the required avalanche and signal induction regions of a PIM-like configuration are studied. The motivation of this work is to understand the electron transfer process in Micromegas and PIMs constructed by using relatively thick woven micromeshes. We have attempted to find optimized PIM configurations in order to obtain high gas gain, fast rise time and other desirable detector properties.