Charge collection efficiency of scCVD diamond detectors at low temperatures

“…In an ideal case, the current response of a 500 µm-thick diamond radiation detector is expected to rise as the bias voltage is increased [12]. However, as shown in Figure (5), the current response of the detector under PB test method, did not show a consistent increase, rather it peaked at +140 V, and became erratic as the bias voltage was further raised.…”

“…Both 12 C and 13 C could capture a neutron and absorb its energy, the most prominent reactions of which are 12 C(n,) 9 Be, 12 C(n, n+2) 4 He, and 13 C(n,) 10 Be, which yield 6 -10 MeV per interaction [6]. Additionally, neutrons could elastically scatter off 12 C and 13 C atoms, which deposits 1.8 to 2.0 MeV per interaction. Lastly, even though less frequently, neutrons could cause (n,) reaction which generates a gamma ray with several MeV energy.…”

“…However, in a practical detector, charge carriers often can get trapped at various defect sites such as: inclusions, grain boundaries, and plane dislocations in the diamond bulk [9 Besides the detection mechanism by its principles creates further inclusions, vacancies and damages.]. Several reports indicate that the density of traps in a SC CVD diamond detector increases progressively over a duration of each continuous use [7][8][9][10][11][12]. The accumulation of charges at defect sites as shown in Figure ( 1) could then result in an emergence of an internal electric field (E in ) between oppositely charged defect sites.…”

Direct current mode neutron detection, investigation of polarization effect on 500 μm single crystal CVD diamond detector, and depolarization techniques

“…In an ideal case, the current response of a 500 µm-thick diamond radiation detector is expected to rise as the bias voltage is increased [12]. However, as shown in Figure (5), the current response of the detector under PB test method, did not show a consistent increase, rather it peaked at +140 V, and became erratic as the bias voltage was further raised.…”

“…Both 12 C and 13 C could capture a neutron and absorb its energy, the most prominent reactions of which are 12 C(n,) 9 Be, 12 C(n, n+2) 4 He, and 13 C(n,) 10 Be, which yield 6 -10 MeV per interaction [6]. Additionally, neutrons could elastically scatter off 12 C and 13 C atoms, which deposits 1.8 to 2.0 MeV per interaction. Lastly, even though less frequently, neutrons could cause (n,) reaction which generates a gamma ray with several MeV energy.…”

“…However, in a practical detector, charge carriers often can get trapped at various defect sites such as: inclusions, grain boundaries, and plane dislocations in the diamond bulk [9 Besides the detection mechanism by its principles creates further inclusions, vacancies and damages.]. Several reports indicate that the density of traps in a SC CVD diamond detector increases progressively over a duration of each continuous use [7][8][9][10][11][12]. The accumulation of charges at defect sites as shown in Figure ( 1) could then result in an emergence of an internal electric field (E in ) between oppositely charged defect sites.…”

Direct current mode neutron detection, investigation of polarization effect on 500 μm single crystal CVD diamond detector, and depolarization techniques

Comparative of HPHT and CVD diamond: performance and defect analysis for alpha radiation detector

Temperature Dependence of Betavoltaic Cell Performance of Diamond pn Junction Diode