Electron radiation effects on a 4H-SiC bipolar phototransistor
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摘要: 当光电晶体管偏置在5 V下,辐照前,其暗电流约为58 nA,对365 nm紫外光的响应度约为31 A/W;器件经过10 MeV电子束辐照后,暗电流的数量级下降到10−11 A,响应度下降到原来的1/8左右。辐照后,器件的响应度受偏置电压的影响明显,随着偏置电压的减小而下降,当光电晶体管偏置在3 V下,响应度下降到2.25 A/W。电子束辐照还会影响紫外探测器的开关响应,使响应的总时间变长。结合光电晶体管工作时的电路模型,电子束辐照后引起光产生电流减小、晶体管增益下降和串联电阻增大是引起光电探测器紫外响应性能退化的主要原因。Abstract: The electron irradiation effect of a 4H-SiC npn bipolar transistor UV detector is investigated in this paper. When the phototransistor is biased at 5 V, before irradiation, its dark current is about 58 nA, and its responsivity to 365 nm UV light is about 31A/W. After the device is irradiated by a 10 MeV e-beam, the order of magnitude of the dark current decreases to 10−11 A, and the responsivity decreases to about 1/8 of the original one. After irradiation, the responsivity of the device is significantly affected by the bias voltage: it decreases as the bias voltage decreases, and when the phototransistor is biased at 3 V, the responsivity decreases to 2.25 A/W. E-beam irradiation also affects the switching response of the UV detector, which results in a longer total time of response. In this paper, the circuit model of phototransistor operation is established, and the decrease of light generation current, the decrease of transistor gain and the increase of series resistance caused by electron beam irradiation are the main reasons for the degradation of photodetector’s UV response performance.
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图 4 不同光强下辐照前后光电晶体管I-V特性
Figure 4. Phototransistor I-V characteristics before and after irradiation at different light densities
图 5 辐照前后光电晶体管的净光电流与紫外光强的关系图
Figure 5. Net photocurrent versus UV intensity of phototransistors before and after irradiation
图 6 辐照后光电晶体管在不同偏压下的紫外响应
Figure 6. UV response of irradiated phototransistors at different bias voltages
图 7 辐照前后光电晶体管的开关响应
Figure 7. Switching response of phototransistors before and after irradiation
图 8 光照时基极浮置的光电晶体管电路模型
Figure 8. Circuit model of a phototransistor with base floating during illumination
图 9 辐照前实验测试与模型仿真的光电晶体管紫外响应I-V曲线
Figure 9. I-V curves of phototransistor UV response from experimental test and model simulation before irradiation
图 10 辐照后实验测试与模型仿真的光电晶体管紫外响应I-V曲线
Figure 10. I-V curves of phototransistor UV response after irradiation with experimental test and model simulation
表 1 实验结果辐照前后探测器性能对比
Table 1. Comparison of detector performance before and after irradiation
dark current (Vce=5 V)/A photocurrent (Vce=5 V)/A photo responsivity/(A·W−1) 110 µW/cm2 220 µW/cm2 Vce=3V Vce=4V Vce=5V pre-irradiation 5.86×10−8 7.43×10−7 1.22×10−6 31.094 31.288 31.306 electron-irradiated 3.73×10−11 9.05×10−8 1.21×10−7 2.251 2.973 3.723 
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