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个人信息Personal Information
副教授 硕士生导师
招生学科专业:
核科学与技术 -- 【招收硕士研究生】 -- 材料科学与技术学院
能源动力 -- 【招收硕士研究生】 -- 材料科学与技术学院
主要任职:系副主任
其他任职:工信部重点实验室主任助理
毕业院校:南京航空航天大学
学历:南京航空航天大学
学位:工学博士学位
所在单位:材料科学与技术学院核科学与技术系
办公地点:将军路校区1号楼11303B室
联系方式:15996240685
电子邮箱:
Vacuum degree effects on betavoltaics irradiated by63Ni with differently apparent activity densities
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所属单位:材料科学与技术学院
发表刊物:Sci. China Technol. Sci.
摘要:For many current betavoltaics, beta sources and PN junction energy conversion units are separated. The air gap between the two parts could stop part of decay beta particles, which results in inefficient performance of the betavoltaic. By employing63Ni with an apparent emission activity density of 7.26×107and 1.81×108Bq cm−2, betavoltaic performance levels were calculated at a vacuum degree range of 1×105to 1×10−1Pa and measured at 1.0×105and 1.0×104Pa, respectively. Results show that betavoltaic performance levels improve significantly as the vacuum degree increases. The maximum output power (Pmax) exhibits the largest change, followed by short-circuit current (Isc), open-circuit voltage (Voc), and fill factor. The vacuum degree effects on Isc, Voc, and Pmaxof the betavoltaic with low apparent activity density63Ni are more significant than those of the betavoltaic with high apparent activity density63Ni. Moreover, the improved efficiencies of the measured performances are larger than the calculated efficiencies because of the low ratio of Iscand reverse saturation current (I0). The values of I0, ideality factor, and shunt resistance were estimated to modify the equivalent circuit model. The calculation results based on this model are closer to the measurement results. The results of this research can provide a theoretical foundation and experimental reference for the study of vacuum degree effects on betavoltaics of the same kind. © 2016, Science China Press and Springer-Verlag Berlin Heidelberg.
卷号:60
期号:2
页面范围:282-288
ISSN号:1674-7321
是否译文:否
发表时间:2017-02-01
收录刊物:EI