%0 Journal Article
%T 63Ni-Si辐射伏特电池镍薄膜源设计与制备<br>Design and fabrication of a 63Ni thin film source for a 63Ni-Si betavoltaic battery
%A 李浩
%A 张高飞
%A 尤政
%J 清华大学学报（自然科学版）
%D 2017
%R 10.16511/j.cnki.qhdxxb.2017.22.042
%X 在辐射伏特电池换能器件表面直接制备63Ni辐射源的方法存在加载量少、活性低、PN结性能退化等问题。该文提出一种利用氧化铟锡（ITO）薄膜作为导电层材料实现在透明封装玻璃表面电镀63Ni源的方法。根据辐射源自吸收效应理论模拟计算了63Ni-Si辐射伏特电池辐射源的最佳厚度。采用磁控溅射工艺在400 μm玻璃基底上制备了厚度为180 nm的ITO导电薄膜，利用电化学工作站，对ITO薄膜表面进行电镀镍，对镀镍之后的薄膜材料微观形貌、薄膜厚度进行表征，并对基于该辐射源制备方法的63Ni-Si辐射伏特型同位素电池电学输出性能进行理论仿真，仿真结果表明：在厚度为2 μm、活度为7.25×108 Bq、面积为36 mm2辐射源的辐照下，辐射伏特电池理论上能够输出85.4 nW输出功率。<br>Abstract：Directly preparation of a 63Ni radioisotope source on the surface of a betavoltaic battery has problems such as low loadings, low activation, and functional deterioration of the PN junction. This research demonstrates the use of an indium tin oxide (ITO) membrane as a conductive layer to plate a 63Ni source on the surface of a transparent glass package. Simulations of the radiation self-absorption effect give the optimal thickness of the 63Ni-Si betavoltaic battery. Then, a 180 nm thick ITO conductive membrane is prepared on a 400 μm thick glass substrate via magnetron sputtering. 63Ni is then electroplated on the ITO membrane surface. The micro-morphology and the Ni-electroplated membrane thickness are characterized. The electrical capabilities of the 63Ni-Si betavoltaic battery fabricated based on this radiation source preparation method are then simulated. The results show that irradiation of a 2 μm thick, 7.25×108 Bq activity, 36 mm2 radiation source gives a radioisotope battery that can export 85.4 nW output power.
%K 辐射伏特电池
%K 63Ni
%K 电镀
%K 辐射源
%K &lt
%K br&gt
%K betavoltaic battery
%K 63Ni
%K electroplate
%K radioisotope source
%U http://jst.tsinghuajournals.com/CN/Y2017/V57/I8/810