钙钛矿太阳电池载流子传输-复合模型研究

通过对所制备的钙钛矿太阳电池进行交流阻抗测试,比较钙钛矿电池载流子扩散长度、载流子寿命、内部电阻及电容等参数,得出在钙钛矿太阳电池中载流子在空穴传输层扩散的特征频率约为2μs^(-1),载流子传输过程快慢顺序依次为:载流子在空穴传输层的传输、钙钛矿薄膜中的传输。另外还得出载流子在钙钛矿薄膜中的复合阻抗是构成电池总阻抗的主要部分,其值远大于空穴传输层的阻抗,约为空穴传输层的15倍。

空间用GaInP/GaAs/Ge三结太阳电池的抗辐照性能及退化机制研究

利用TFC光学膜系设计软件,设计出空间用GaInP/(In)GaAs/Ge三结太阳电池的分布式布拉格反射器(DBR)。由15对Al0.2Ga0.8As/Al0.9Ga0.1As组成的布拉格反射器在中心波长850 nm处反射率高达96%,可以使800~900 nm波段内红外光有效反射后被二次吸收,提高了Ga As子电池的抗辐照能力。通过对两种电池结构A、B地面模拟辐照试验获得1 Me V电子辐照下Ga In P/Ga As/Ge太阳电池电学参数随辐照注量退化的基本规律。在此基础上应用PC1D模拟程序分析太阳电池内部的载流子输运机理,建立1 Me V电子辐照下两种电池结构中多数载流子浓度和少数载流子扩散长度随辐照电子注量变化的基本规律。研究结果表明,多数载流子浓度和少数载流子扩散长度均随入射电子注量的增大而减小,同时原电池结构A中多数载流子去除率和少数载流子扩散长度损伤系数明显高于新电池结构B,由此表明包含布拉格反射器的新电池结构具有更强的抗辐照能力。

电子辐照下GaAs/Ge太阳电池性能退化机制

通过空间带电粒子辐照地面等效模拟实验得到1 Me V和1.8 Me V电子辐照下GaAs/Ge太阳电池电学性能退化规律。根据太阳电池电学参数退化模型,对太阳电池短路电流退化曲线进行非线性分析,建立空间GaAs/Ge太阳电池少数载流子扩散长度损伤系数随入射电子能量变化的基本规律。结果表明,少数载流子扩散长度损伤系数随入射电子能量的增高而增大,这与短路电流退化幅度随电子能量变化规律一致。

电子辐照下GaAs/Ge太阳电池载流子输运机理研究

通过地面模拟辐照试验获得不同能量电子辐照下GaAs/Ge太阳电池电学参数退化的基本规律,在此基础上使用PC1D模拟程序分析太阳电池内部的载流子输运机理,建立不同能量的电子辐照下GaAs/Ge太阳电池中多数载流子浓度和少数载流子扩散长度随辐照粒子注量变化的基本规律.研究结果表明:多数载流子浓度和少数载流子扩散长度均随入射电子注量的增大而减小,多数载流子去除率和少数载流子扩散长度损伤系数均随电子能量的增高而增大,多数载流子去除效应和少数载流子扩散长度缩短分别是电池开路电压和短路电流退化的主要原因.

Study on device simulation and performance optimization of the epitaxial crystalline silicon thin film solar cell

Because crystalline silicon thin film （CSiTF） solar cells possess the advantages of crystalline silicon solar cells such as high ef- ficiency and stable performance and those of thin film solar cells such as low cost and so on, it is regarded as the next genera- tion solar cell technology, which is most likely to replace the existing crystalline silicon solar cell technology. In this paper, we performed device simulation on the epitaxial CSiTF solar cell by using PCI D software. In order to make simulation results closer to the actual situation, we adopted a more realistic device structure and parameters. On this basis, we comprehensively and systematically investigated the effect of physical parameters of back surface field （BSF） layer, base and emitter, electrical quality of crystalline silicon active layer, situation of surface passivation, internal recombination and p-n junction leakage on the optoelectronic performance of the epitaxial CSiTF solar cell. Among various factors affecting the efficiency of the epitaxial CSiTF solar cell, we identified the three largest efficiency-affecting parameters. They are the base minority carrier diffusion length, the diode dark saturation current and the front surface recombination velocity in order. Through simulations, we found that the base is not the thicker the better, and the base minority carrier diffusion length must be taken into account when deter- mining the optimal base thickness. When the base minority carrier diffusion length is smaller, the optimal base thickness should be less than or equal to the base minority carrier diffusion length; when the base minority carrier diffusion length is larger, the base minority carrier diffusion length should be at least twice the optimal base thickness. In addition, this paper not only illustrates the simulation results but also explains their changes from the aspect of physical mechanisms. Because epitaxi- al CSiTF solar cells possess a device structure that is similar to crystalline silicon solar cells, the conclusions drawn in this pa- per are also applied to crystalline silicon solar cells to a certain extent, particularly to thin silicon solar cells which are the hot- test research topic at present.