Radiation tolerance of a diamond radiation detector for space use

We present a study of the radiation tolerance of two types of diamond radiation detectors for space use.

We plan to launch a 3U-size CubeSat, KSAT3-X, developed by Kanazawa University in 2027.

The KSAT3-X mission is aimed to observe inflows and outflows of charged particles such as electrons and protons, particularly in the 10 - 40 keV energy range, in the Earth's magnetosphere.

As the mission instrument, we have developed two diamond radiation detectors.

The first is composed of a microwave plasma chemical vapor deposition (MPCVD) diamond fabricated by Element Six, and the second is based on a MPCVD diamond produced in-house at Kanazawa University.

We irradiate both diamonds with 100 MeV protons and evaluate their spectroscopic performance as an indicator of radiation tolerance using characteristic X-rays from radioisotope sources.

We find no significant degradation in their spectroscopic performance up to at least the 10-year equivalent irradiation under the orbital environments of KSAT3-X.

We additionally irradiate the Element Six diamond with 100 MeV protons up to the 100-year equivalent.

As a result, no significant degradation in the spectroscopic performance is observed.

These results indicate that the two diamond radiation detectors have sufficiently high radiation tolerance.

We also discuss possible physical origins of the observed difference in the spectroscopic performance between the two detectors.