Ion Microprobe Study of the Polarization Quenching Techniques in Single Crystal Diamond Radiation Detectors

Abstract: Synthetic single crystal diamond grown using the chemical vapor deposition technique constitutes an extraordinary candidate material for monitoring radiation in extreme environments. However, under certain conditions, a progressive creation of space charge regions within the crystal can lead to the deterioration of charge collection efficiency. This phenomenon is called polarization and represents one of the major drawbacks associated with using this type of device. In this study, we explore different techniqu… Show more

“…However, the external field is not strong enough to de-trap carriers from trap sites, which causes fluctuating internal electric field and instability in the measured detector current. An additional increase in bias will give it sufficient strength to de-trap carriers, which could limit the effect of polarization [9]. Furthermore, increase in dark current is caused by late relaxing carriers.…”

“…Assuming similar composition with natural diamond, the isotopic abundance of CVD diamond is 98.93% carbon-12 ( 12 C) and 1.07% carbon-13 ( 13 C) [5]. 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.…”

“…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.…”

“…Consequently, a small variation in the net applied electric field has a pronounced effect on the reliability of the measurement. Reports have shown the strength and polarity of the applied electric field influences the trapping and detrapping dynamics of charge carriers [9][10][11]. Therefore, a study on the DC response of a SC CVD diamond neutron detector under various electric field values is necessary to understand the effect of measurement conditions on overall DC response of the detector.…”

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

“…However, the external field is not strong enough to de-trap carriers from trap sites, which causes fluctuating internal electric field and instability in the measured detector current. An additional increase in bias will give it sufficient strength to de-trap carriers, which could limit the effect of polarization [9]. Furthermore, increase in dark current is caused by late relaxing carriers.…”

“…Assuming similar composition with natural diamond, the isotopic abundance of CVD diamond is 98.93% carbon-12 ( 12 C) and 1.07% carbon-13 ( 13 C) [5]. 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.…”

“…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.…”

“…Consequently, a small variation in the net applied electric field has a pronounced effect on the reliability of the measurement. Reports have shown the strength and polarity of the applied electric field influences the trapping and detrapping dynamics of charge carriers [9][10][11]. Therefore, a study on the DC response of a SC CVD diamond neutron detector under various electric field values is necessary to understand the effect of measurement conditions on overall DC response of the detector.…”

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

“…Diamond is a unique material with a number of record-breaking properties. Its electrical breakdown threshold is up to 2-10 MV/cm [1][2][3], making it attractive for highvoltage applications, such as field electron transistors [4][5][6][7][8], switching diodes [9][10][11][12][13], highenergy particle trapping [14][15][16][17][18], photoconductive antennas [19][20][21][22] and others. The thermal conductivity of diamond (24 W/cm•K) [23] is even higher than that of copper, which allows it to effectively dissipate heat [24][25][26][27][28].…”

CVD Encapsulation of Laser-Graphitized Electrodes in Diamond Electro-Optical Devices

Charge collection efficiency of scCVD diamond detectors at low temperatures