Validation of Thin-foil proton recoil neutron spectrometer prototype for application in high yield DT fusion devices

TL;DR

This study validates a prototype Thin-foil Proton Recoil neutron spectrometer for high-yield DT fusion devices by comparing experimental results with Geant4 simulations, confirming its potential for neutron monitoring in fusion reactors like ITER.

Contribution

The paper presents the first experimental validation of a TPR neutron spectrometer prototype and its Geant4 simulation model for fusion applications.

Findings

Experimental results match simulations within detector resolution.

Energy calibration using silicon nuclear reactions is feasible.

Detector efficiency estimates require refinement.

Abstract

The use of Thin-foil Proton Recoil (TPR) spectrometers for application in neutron spectroscopy is of high relevance for future fusion devices such as ITER, where neutron spectroscopy will play a crucial role in fuel content monitoring. Existing research based on simulations of the performance of TPR spectrometers at ITER has demonstrated positive results. However, experimental validation of the simulations would greatly benefit the reliability of conclusions. In this study, we designed and constructed a prototype TPR neutron spectrometer and employed a DT neutron generator as a neutron source to perform measurements. We compared the experimental results with the simulation results using the Geant4 model of the experiment. The simulation and experimental results match within silicon detector intrinsic energy resolution. This approach ensures the experimental validation of the Geant4 based simulations of the TPR spectrometer. The experimental results demonstrated the feasibility of utilizing nuclear reactions measured in silicon detectors, specifically $^{28}$Si(n,d) and $^{28}$Si(n,$\alpha$), for energy calibration purposes. A comparison of the experiment and the simulation shows that the mean peak energy and full width at half maximum are within 150 keV. The calculated detector efficiency underestimates the experimentally determined efficiency up to 33\%. Discrepancies in the measured energy spectrum indicate the need for a more refined model and experiment control. Overall, the successful validation of the developed Geant4 simulation model against the experimentally measured energy spectra increases confidence in the applicability of such simulation results in other devices. The demonstrated energy calibration highlights new possibilities for neutron spectrometer monitoring during operation at ITER.