Spatial resolution of a {\mu}PIC-based neutron imaging detector

TL;DR

This paper demonstrates a new neutron imaging detector using a {b5}PIC that achieves significantly improved spatial resolution of around 103 micrometers, suitable for high-rate neutron radiography and spectroscopy applications.

Contribution

The study introduces a novel neutron position reconstruction method for {b5}PIC-based detectors, enhancing spatial resolution and efficiency over previous techniques.

Findings

Achieved a spatial resolution of approximately 103 micrometers.

Improved from 334 micrometers with previous methods.

Potential to reach below 60 micrometers with further optimization.

Abstract

We present a detailed study of the spatial resolution of our time-resolved neutron imaging detector utilizing a new neutron position reconstruction method that improves both spatial resolution and event reconstruction efficiency. Our prototype detector system, employing a micro-pattern gaseous detector known as the micro-pixel chamber ({\mu}PIC) coupled with a field-programmable-gate-array-based data acquisition system, combines 100{\mu}m-level spatial and sub-{\mu}s time resolutions with excellent gamma rejection and high data rates, making it well suited for applications in neutron radiography at high-intensity, pulsed neutron sources. From data taken at the Materials and Life Science Experimental Facility within the Japan Proton Accelerator Research Complex (J-PARC), the spatial resolution was found to be approximately Gaussian with a sigma of 103.48 +/- 0.77 {\mu}m (after correcting for beam divergence). This is a significant improvement over that achievable with our previous reconstruction method (334 +/- 13 {\mu}m), and compares well with conventional neutron imaging detectors and with other high-rate detectors currently under development. Further, a detector simulation indicates that a spatial resolution of less than 60 {\mu}m may be possible with optimization of the gas characteristics and {\mu}PIC structure. We also present an example of imaging combined with neutron resonance absorption spectroscopy.