The Architected Multi-material Scintillator System: Designs and Modeling

TL;DR

This paper introduces a novel multi-material scintillator system with architected structures that encode additional information in radiation detection, enabling advanced capabilities like directional detection and position sensing through additive manufacturing.

Contribution

The paper proposes and models a new multi-material scintillator design that encodes information via structured dye arrangements, enhancing radiation detection capabilities beyond traditional systems.

Findings

Simulations show improved particle identification and directionality.

Dye gradients enable precise radiation position sensing.

Architected structures enhance multi-capability performance.

Abstract

We present a new conceptual radiation detector, the Architected Multimaterial Scintillator System, that utilizes a scintillator composed of multiple materials arranged in architected structures to enable new capabilities. By structuring differently-dyed materials, the wavelength of the scintillation light encodes additional information in radiation measurements. These structures can be realized through additive manufacture (3D-printing). Two classes of this concept are described and modelled using Monte Carlo simulations to evaluate their performance. The first detector design uses dye microstructures to encode particle tracking information, allowing for directional neutron detection and gamma/neutron discrimination. The second design uses a dye gradient to indicate the position of radiation along the gradient. The simulation results indicate this new concept in radiation detection can achieve strong performance in a variety of capabilities including particle identification, directionality and spectroscopy measurements, and particle position reconstruction.