TL;DR
This paper introduces a novel optical gaseous detector, the O-PPAC, for heavy-ion tracking, combining Monte Carlo optimization and experimental validation to achieve sub-millimeter localization accuracy.
Contribution
The paper presents the design, simulation, and experimental validation of a new optical parallel-plate avalanche counter with improved spatial resolution.
Findings
Simulation optimized the detector geometry for high resolution.
Prototype demonstrated sub-millimeter localization capability.
Experimental results aligned well with simulations.
Abstract
We describe a novel gaseous detector concept for heavy-ion tracking and imaging: the Optical Parallel-Plate Avalanche Counter (O-PPAC). The detector consists of two thin parallel-plate electrodes separated by a small (typically 3 mm) gap filled with low-pressure scintillating gas (i.e. CF4). The localization of the impinging particles is achieved by recording the secondary scintillation, created during the avalanche processes within the gas gap, with dedicated position-sensitive optical readouts. The latter may comprise arrays of collimated photo-sensors (e.g. SiPMs) that surround the PPAC effective area. We present a systematic Monte Carlo simulation study used to optimize the geometry of the OPPAC components, including SiPMs effective area, collimator dimensions, and operational conditions. It was found that the optimal design for 10x10 cm^2 OPPAC detector comprises four arrays, each…
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