The initial measurement of a compact D–T neutron spectrometer based on a single-crystal chemical vapor deposition diamond stack for fusion plasma diagnostic

Abstract

For developing and characterizing a novel compact D–T neutron spectrometer based on a single-crystal chemical vapor deposition diamond stack for plasma diagnostics toward future D–T fusion reactors, the initial measurement was performed using the accelerator-based D–T neutron sources OKTAVIAN at Osaka University. This neutron spectrometer was designed for the detection of 3–17 MeV neutrons and operated in the proton recoil telescope configuration by installing a polyethylene converter in front of the diamond stack. The measured neutron energy spectra were obtained by summing the energy of the recoil protons deposited in the diamond stack after the coincidence of the recoil protons identified by the time coincidence analysis. The neutron energy peaks measured by the compact D–T neutron spectrometer were almost in agreement with those obtained by the Monte Carlo N-Particle transport (MCNP) simulation. The energy resolution of the compact D–T neutron spectrometer was emulated to be about 4%–5% in D–T neutron measurement. In future work, the design of the compact D–T neutron spectrometer would be optimized to measure the fusion neutron for plasma diagnostics.