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PC1 D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.     

100 keV质子辐照对空间GaAs/Ge太阳电池光电效应的影响

利用空间环境模拟设备,用固定能量为100keV、注量为1×10⁹—3×10¹²cm^-2的质子,对空间实用GaAs/Ge太阳电池进行了辐照试验.利用伏安(I-V)特性、光谱响应和光致发光(PL)光谱测试,研究分析了电池的光电效应.试验表明,电池的各种电性能参数如短路电流(I_sc)、开路电压(V_oc)、最大输出功率(P_{m< 关键词： GaAs/Ge太阳电池 质子辐照 光电效应}     

GaInP/GaAs/Ge三结太阳电池不同能量质子辐照损伤模拟

以GaInP/GaAs/Ge三结太阳电池为研究对象,开展了能量为0.7, 1, 3, 5, 10 MeV的质子辐照损伤模拟研究,建立了三结太阳电池结构模型和不同能量质子辐照模型,获得了不同质子辐照条件下的I-V曲线,光谱响应曲线,结合已有实验结果验证了本文模拟结果,分析了三结太阳电池短路电流、开路电压、最大功率、光谱响应随质子能量的变化规律,利用不同辐照条件下三结太阳电池最大输出功率退化结果,拟合得到了三结太阳电池最大输出功率随位移损伤剂量的退化曲线.研究结果表明,质子辐照会在三结太阳电池中引入位移损伤缺陷,使得少数载流子扩散长度退化幅度随质子能量的减小而增大,从而导致三结太阳电池相关电学参数的退化随质子能量的减小而增大.相同辐照条件下,中电池光谱响应退化幅度远大于顶电池光谱响应退化幅度,中电池抗辐照性能较差,同时中电池长波范围内光谱响应的退化幅度比短波范围更大,表明中电池相关电学参数的退化主要来源于基区损伤.     

Temperature and 8 MeV electron irradiation effects on GaAs solar cells

GaAs solar cells hold the record for the highest single band-gap cell efficiency. Successful application of these cells in advanced space-borne systems demand characterization of cell properties like dark current under different ambient conditions and the stability of the cells against particle irradiation in space. In this paper, the results of the studies carried out on the effect of 8 MeV electron irradiation on the electrical properties of GaAs solar cells are presented. The I–V (current-voltage) characteristics of the cells under dark and AM1.5 illumination condition are studied and 8 MeV electron irradiation was carried out on the cells where they were exposed to graded doses of electrons from 1 to 100 kGy. The devices were also characterized using capacitance measurements at various frequencies before and after irradiation. The effect of electron irradiation on the solar cell parameters was studied. It is found that only small changes were observed in the GaAs solar cell parameters up to an electron dose of 100 kGy, exhibiting good tolerance for electrons of 8 MeV energy.     

GaInP/GaAs/Ge三结太阳电池的电子辐照损伤效应

研究了1 MeV和1.8 MeV电子辐照下GaInP/GaAs/Ge三结太阳电池的辐照损伤效应.电学性能研究结果表明,GaInP/GaAs/Ge三结太阳电池的开路电压、短路电流和最大功率随辐照剂量的增加发生明显衰降,在1 MeV电子辐照下剂量为1×10¹⁵cm^-2时,与辐照前相比最大功率衰降了17.7%.暗I-V特性分析表明,高能电子辐照下三结电池串、并联电阻的变化是引起太阳电池电学性能衰降的重要原因.光谱响应分析结果表明,GaInP 关键词： GaInP/GaAs/Ge太阳电池 电子辐照 电学性能 光谱响应     

Design and modeling of an efficient metamorphic dual-junction InGaP/GaAs solar cell

In this work the impact of variation in mole fraction of tunnel junction and doping concentration of top window layer are investigated on the photovoltaic performance of dual junction InGaP/GaAs solar cell on silicon substrate. How does the Si substrate help this structure to act as a low cost concentrator cell for terrestrial application is also discussed. The detailed analysis of the cell is carried out through the performance measurement such as external quantum efficiency, internal quantum efficiency, fill factor, open circuit voltage, short circuit current density, spectral density and reflectance. This simulation model provides efficiency of 30.40 % at AM1.5G spectrum under 1 sun. It provides a path to the researcher for the development of III–V multi junction solar cell at a low cost.     

基于分布式布拉格反射器结构的空间三结砷化镓太阳能电池抗辐照研究

根据电子辐照条件下的常规三结砷化镓太阳能电池光谱响应以及电池电流的损伤特征, 确定电池衰减的物理机理: 中电池在电子辐照后形成的辐照损伤缺陷, 使得基区少子扩散长度被大幅缩短, 影响了光生载流子的收集. 针对中电池衰减的物理机理, 设计不同的基区厚度, 验证辐照后扩散长度缩短至1.5 μm左右. 为提升中电池抗辐照性能, 消除辐照后扩散长度缩减带来的影响, 对中电池外延结构进行设计, 将中电池基区减薄至1.5 μm, 并在其下方嵌入分布式布拉格反射器, 对特定波段光反射进行二次吸收, 弥补中电池减薄的影响. 通过TFCalc光学模系设计软件模拟出的中心波长为850 nm, 15对Al_0.9Ga_0.1As/Al_0.1Ga_0.9As的分布式布拉格反射器, 实际测试最高反射率大于97%, 高反带宽94 nm, 能够满足设计要求. 此基础上进行了新结构电池的外延生长与辐照测试对比. 实验结果表明: 新结构太阳能电池辐照后短路电流衰减比原结构降低了50%, 效率的剩余因子提升2.3%.     

基于GaAs/InAs-GaAs/ZnSe量子点太阳电池结构的优化

基于GaAs/InAs-GaAs/ZnSe的P-i-N量子点太阳电池结构, 根据光学原理和扩散理论建立了光生电流密度与膜层厚度相关的数学模型, 定量分析了量子点层厚度等参数对太阳电池性能的影响,以期达到提高量子 点太阳电池转换效率的目的.理论模拟表明:在i层厚度取3000 nm时,优化后P(GaAs)型、N(ZnSe)型层 薄膜的最佳膜厚为1541 nm, 78 nm, 并在单一波长下太阳电池转换效率为20.1%;同时量子 点体积和温度对于量子点太阳电池I-V特性也会产生影响, 当量子点体积和温度逐渐增大时, 开路电压呈现减小趋势,使得转换效率降低.     

空间用倒装三结太阳能电池及其抗辐射性能研究

使用金属有机化学气相沉积技术,在4英寸GaAs衬底上获得了空间用GaInP/GaAs/In_(0.3)Ga_(0.7)As倒装三结太阳能电池.高分辨X射线衍射和阴极射线发光测试结果表明AlInGaAs应力渐变缓冲层的晶格弛豫度约100%,其整面平均穿透位错密度约5.4×10~6/cm~2.与GaInP/InGaAs/Ge常规三结太阳能电池相比,在AM0光谱、25℃测试条件下,面积24 cm~2的倒装三结太阳能电池转换效率达到32%,输出功率提高了5%.采用1 MeV高能电子对倒装三结电池进行粒子辐照测试,电池各项性能参数随不同辐照剂量发生改变,在1×10~(15)/cm~2辐照总剂量下电池转换效率衰降比例达到15%.     

Defect generation in polycrystalline Cu(In,Ga)Se2 by high-energy electron irradiation

We investigate the degradation of ZnO/CdS/ Cu(In,Ga)Se₂ heterojunction solar cells for space applications and the defect generation in polycrystalline Cu(In,Ga)Se₂ thin films by irradiation with 1-MeV electrons with fluences J_e up to J_e=5᎒¹⁸ cm^-2. Notable degradation of the solar cell performance starts at fluences of J_e=10¹⁷ cm^-2 where the open circuit voltage decreases by about 5% while short circuit current and fill factor remain essentially unaffected. Thus, Cu(In,Ga)Se₂ solar cells withstand electron fluences which are higher by one order of magnitude or more when compared to other technologies. A model describes the absolute open circuit voltage loss considering the increase of space charge recombination by electron irradiation-induced defects. Defect analysis by admittance spectroscopy shows that acceptor defects with an energy distance of approximately 300 meV from the valence band are generated at a rate %=0.017 (ǂ.01) cm^-1.     

非晶硅锗电池性能的调控研究

采用射频等离子体增强化学气相沉积技术, 研究了非晶硅锗薄膜太阳电池. 针对非晶硅锗薄膜材料的本身特性, 通过调控硅锗合金中硅锗的比例, 实现了对硅锗薄膜太阳电池中开路电压和短路电流密度的分别控制. 借助于本征层硅锗材料帯隙梯度的设计, 获得了可有效用于多结叠层电池中的非晶硅锗电池. 关键词： 非晶硅锗薄膜太阳电池 短路电流密度 开路电压 带隙梯度     

聚光光强对光伏电池阵列输出性能的影响

基于槽式聚光热电联供系统,深入分析晶硅电池阵列和砷化镓电池阵列在高倍聚光下的输出特性及输出功率的影响因素.研究结果表明,聚光光强下砷化镓电池阵列输出性能优于晶硅电池阵列,高光强会导致光伏电池禁带宽度变窄,短路电流成倍增加,增加输出功率,但同时耗尽层复合率变大,开路电压降低,制约阵列的输出功率;高光强还引起电池温度升高,电池阵列串联内阻增加.分析表明聚光作用下电池阵列串联内阻对输出功率影响巨大,串联内阻从0 Ω增加1 Ω,四种电池阵列输出功率分别损失67.78%,74.93%,77.30%和58.01%. 关键词： 热电联供 太阳电池阵列 串联内阻 输出功率     

Degradation behavior of electrical properties of GaInAs (1.0 eV) and GaInAs (0.7 eV) sub-cells of IMM4J solar cells under1-MeV electron irradiation

In this work the degradation effects of the Ga_(0.7)In_(0.3)As(1.0 eV) and Ga_(0.42)In_(0.58)As(0.7 eV) sub-cells for IMM4J solar cells are investigated after 1-MeV electron irradiation by using spectral response and photoluminescence(PL) signal amplitude analysis, as well as electrical property measurements. The results show that, compared with the electrical properties of traditional single junction(SJ) GaAs(1.41 eV) solar cell, the electrical properties(such as Isc, Voc, and Pmax)of the newly sub-cells degrade similarly as a function of log ?, where ? represents the electron fluence. It is found that the degradation of Voc is much more than that of Isc in the irradiated Ga_(0.42)In_(0.58)As(0.7 eV) cells due to the additional intrinsic layer, leading to more serious damage to the space charge region. However, of the three types of SJ cells with the gap widths of 0.7, 1.0, and 1.4 eV, the electric properties of the Ga_(0.7)In_(0.3)As(1.0 eV) cell decrease largest under each irradiation fluence. Analysis on the spectral response indicates that the Jsc of the Ga_(0.7)In_(0.3)As(1.0 eV) cell also shows the most severe damage. The PL amplitude measurements qualitatively confirm that the degradation of the effective minority carrier life-time(τeff) in the SJ Ga_(0.7)In_(0.3)As cells is more drastic than that of SJ GaAs cells during the irradiation. Thus,the output current of Ga_(0.7)In_(0.3)As sub-cell should be controlled in the irradiated IMM4J cells.     

Photocarrier radiometry for noncontact evaluation of space monocrystalline silicon solar cell under low-energy electron irradiation

A space monocrystalline silicon(c-Si) solar cell under low-energy( 1 MeV) electron irradiation was investigated using noncontact photocarrier radiometry(PCR). Monte Carlo simulation(MCS) was employed to characterize the effect of different energy electron irradiation on the c-Si solar cell. The carrier transport parameters(carrier lifetime, diffusion coefficient, and surface recombination velocities) were obtained by best fitting the experimental results with a theoretical one-dimensional two-layer PCR model. The results showed that the increase of the irradiation electron energy caused a large reduction of the carrier lifetime and diffusion length. Furthermore, the rear surface recombination velocity of the Si:p base of the solar cell at the irradiation electron energy of 1 Me V was dramatically enhanced due to 1 MeV electron passing through the whole cell. Short-circuit current(I sc) degradation evaluated by PCR was in good agreement with that obtained by electrical measurement.     

有机共混结构叠层太阳电池的研究进展

有机太阳电池由于质轻、价廉、柔性,受到人们的广泛关注.单个有机材料只能吸收部分太阳光,叠层结构的太阳电池将不同吸收带隙的有机材料通过中间层连接起来,既能充分吸收太阳光,又能提高太阳电池的开路电压或短路电流.本文综述了近年来有机共混结构叠层太阳电池的研究进展,介绍了各种叠层有机太阳电池的结构、原理及性能,阐述了国内外有机叠层太阳电池研究的现状及存在问题,为高性能有机太阳电池的研究提供有价值的参考.     

位移损伤剂量法评估空间GaAs/Ge太阳电池辐照损伤过程

本文针对GaAs/Ge太阳电池,利用位移损伤剂量法研究了其在轨服役条件下的性能退化行为.首先在地面模拟辐照环境中,试验获得了在不同能量的电子和质子辐照下的电池性能随辐照注量的退化行为.基于上述实验结果以及计算获得的带电粒子在电池中的非电离能量损失(NIEL)获得了不同能量电子辐照位移损伤的等效指数n为1.7,电子损伤剂量转化为质子损伤剂量等效系数为5.2,并进一步建立了电池性能随位移损伤剂量的退化方程.利用该方法对国产GaAs/Ge太阳电池在500,22000和36000 km轨道带电粒子辐 关键词： GaAs/Ge太阳电池 辐照损伤 带电粒子 位移损伤剂量     

Low-temperature-processed ZnO thin films as electron transporting layer to achieve stable perovskite solar cells

Morphology and surface property of ZnO thin films as electron transporting layer in perovskite solar cells are crucial for obtaining high-efficient and stable perovskite solar cells. In this work, two different preparation methods of ZnO thin films were carried out and the photovoltaic performances of the subsequent perovskite solar cells were investigated. ZnO thin film prepared by sol–gel method was homogenous but provided high series resistance in solar cells, leading to low short circuit current density. Lower series resistance of solar cell was obtained from homogeneous ZnO thin film from spin-coating of colloidal ZnO nanoparticles (synthesized by hydrolysis–condensation) in a mixture of 1-butanol, chloroform and methanol. The perovskite solar cells using this film achieved the highest power conversion efficiency (PCE) of 4.79% when poly(3-hexylthiophene) was used as a hole transporting layer. In addition, the stability of perovskite solar cells was also examined by measuring the photovoltaic characteristic for six consecutive weeks with the interval of 2 weeks. It was found that using double layers of the sol–gel ZnO and ZnO nanoparticles provided better stability with no degradation of PCE in 10 weeks. Therefore, this work provides a simple method for preparing homogeneous ZnO thin films in order to achieve stable perovskite solar cells, also for controlling their surface properties which help better understand the characteristics of perovskite solar cells.     

Investigation of nuclear quantum effect on the hydrogen bonds of ammonium dihydrogen phosphate using single-crystal neutron diffraction and theoretical modelling

The heterostructure of patterned CdS / CdTe thin films with back contact have been devised with electron beam lithography and fabricated using sputter deposition technique. The metallic contacts for n-CdS and p-CdTe are patterned such that both are placed at the bottom of the cell. This avoids losses due to contact shading and increases absorption in the window layer. Patterning of the device surface helps in increasing the junction area which can modulate the absorption of more number of photons due to total internal reflection. Computing the surface area between a planar and a patterned device has revealed 133% increase in the junction area. The physical and optical properties of the sputter-deposited CdS / CdTe layers are also presented. J–V characteristics of the solar cell showed the fill factor to be 25.9%, open circuit voltage to be 17 mV and short-circuit current density to be \(113.68~\hbox {A}/\hbox {m}^{2}\). The increase in surface area is directly related to the increase in the short circuit current of the photovoltaic cell, which is observed from the results of simulated model in Atlas / Silvaco.     

基于杂质光伏效应的镍掺杂对砷化镓太阳电池性能的影响

利用杂质光伏效应能够使太阳电池充分利用那些能量小于禁带宽度的太阳光子,从而提高电池的转换效率.为了更好地利用杂质光伏效应提高砷化镓太阳电池的转换效率,本文利用数值方法研究在砷化镓太阳电池中掺入镍杂质以形成杂质光伏太阳电池,分析掺镍对电池的短路电流密度、开路电压以及转换效率的影响;同时,探讨电池的陷光结构对杂质光伏太阳电池器件性能的影响.结果表明:利用杂质光伏效应掺入镍杂质能够增加子带光子的吸收,使得电池转换效率提高3.32%;转换效率的提高在于杂质光伏效应使电池的红外光谱响应得到扩展;另外,拥有良好的陷光结构是取得好的杂质光伏效应的关键.由此得出:在砷化镓太阳电池中掺镍形成杂质光伏太阳电池是一种能够提高砷化镓太阳电池转换效率的新方法.