Response of diamond detector sandwich to 14 MeV neutrons

TL;DR

This study evaluates the response of ultra-thin diamond detectors to 14 MeV neutrons, demonstrating their potential for high-fluence neutron detection in fusion reactors with good energy resolution.

Contribution

It introduces a novel 50 μm thick diamond sandwich detector for neutron detection, showing high durability and accurate neutron energy measurement.

Findings

Detection sensitivity of 5×10^{-7} counts cm^2/n

Energy resolution of 240 keV FWHM

Good agreement with Geant4 simulations

Abstract

In this paper we present the measurement of the response of 50 $\mu$m thin diamond detectors to 14 MeV neutrons. Such neutrons are produced in fusion reactors and are of particular interest for ITER neutron diagnostics. Among semiconductor detectors diamond has properties most appropriate for harsh radiation and temperature conditions of a fusion reactor. However, 300-500 $\mu$m thick diamond detectors suffer significant radiation damage already at neutron fluences of the order of $10^{14}$ n/cm$^2$. It is expected that a 50 $\mu$m thick diamond will withstand a fluence of $>10^{16}$ n/cm$^2$. We tested two 50 $\mu$m thick single crystal CVD diamonds, stacked to form a "sandwich" detector for coincidence measurements. The detector measured the conversion of 14 MeV neutrons, impinging on one diamond, into $\alpha$ particles which were detected in the second diamond in coincidence with nuclear recoil. For $^{12}C(n,\alpha)^{9}Be$ reaction the total energy deposited in the detector gives access to the initial neutron energy value. The measured 14 MeV neutron detection sensitivity through this reaction by a detector of effective area 3$\times$3 mm$^2$ was $5\times 10^{-7}$ counts cm$^2$/n. This value is in good agreement with Geant4 simulations. The intrinsic energy resolution of the detector was found to be 240 keV FWHM which adds only 10 % to ITER's 14 MeV neutron energy spread.