Impurity photovoltaic effect in silicon solar cells doped with two impurities

In this work, a numerical study has been carried out to investigate the impurity photovoltaic (IPV) effect for silicon solar cells doped with two impurities (indium and thallium). It is found that the conversion efficiency \(\eta \) of the IPV solar cell doped with two impurities can improve by 2.21 % absolute, which is greater than that of the IPV solar cell doped with indium ( \(\Delta \eta =1.63\,\%\) ), but less than that of the one doped with thallium ( \(\Delta \eta =2.69\,\%\) ). It is concluded that introducing two IPV impurities may not be a good selection for implementing the IPV effect since one impurity with poorer IPV effect can absorb some sub-bandgap photons while contributing fewer currents. The location of impurity energy level is critical to the IPV cell performance. For an acceptor-type IPV impurity, the optimized location of the IPV impurity energy level locates at 0.20–0.26 eV above the valence band edge. Our results may help to make better use of the IPV effect for improving solar cell efficiency.     

Photoemission cross section:A critical parameter in the impurity photovoltaic effect

A numerical study has been conducted to explore the role of photoemission cross sections in the impurity photovoltaic(IPV) effect for silicon solar cells doped with indium. The photovoltaic parameters(short-circuit current density, opencircuit voltage, and conversion efficiency) of the IPV solar cell were calculated as functions of variable electron and hole photoemission cross sections. The presented results show that the electron and hole photoemission cross sections play critical roles in the IPV effect. When the electron photoemission cross section is 10-20cm~2, the conversion efficiencyη of the IPV cell always has a negative gain(?η 0) if the IPV impurity is introduced. A large hole photoemission cross section can adversely impact IPV solar cell performance. The combination of a small hole photoemission cross section and a large electron photoemission cross section can achieve higher conversion efficiency for the IPV solar cell since a large electron photoemission cross section can enhance the necessary electron transition from the impurity level to the conduction band and a small hole photoemission cross section can reduce the needless sub-bandgap absorption. It is concluded that those impurities with small(large) hole photoemission cross section and large(small) electron photoemission cross section,whose energy levels are near the valence(or conduction) band edge, may be suitable for use in IPV solar cells. These results may help in judging whether or not an impurity is appropriate for use in IPV solar cells according to its electron and hole photoemission cross sections.     

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.     

硅p-n结太阳电池对DF激光的响应

 对硅p-n结太阳电池在DF激光辐照下的响应进行了理论和实验研究。推导了p-n结反向饱和电流随温度的近似变化关系。根据该近似关系，计算了太阳电池在DF激光辐照过程中输出电压的变化曲线。计算结果和实验结果之间取得了比较好的一致性。     

硅p-n结太阳电池对DF激光的响应

对硅p-n结太阳电池在DF激光辐照下的响应进行了理论和实验研究。推导了p-n结反向饱和电流随温度的近似变化关系。根据该近似关系,计算了太阳电池在DF激光辐照过程中输出电压的变化曲线。计算结果和实验结果之间取得了比较好的一致性。     

Characteristics of silicon solar cell emitter with a reduced diffused phosphorus inactive layer

The diffusion of phosphorus using a phosphorous oxychloride (POCl₃) source in silicon has been used widely in crystalline silicon solar cells. The thermal diffusion process in the furnace consists of two steps: pre-deposition and drive-in. The phosphorous doping profile via thermal diffusion often exhibits high concentrations in the surface-near emitter, which result in a recombination increase. This layer, called the dead layer, should be inhibited in order to fabricate high efficiency silicon solar cells. In this paper, the amount of the POCl₃ flow rate was varied during the pre-deposition process in order to minimize the dead layer, and the characteristics of the phosphosilicate glass (PSG) and emitter were analyzed. From the secondary ion mass spectroscopy (SIMS) and electrochemical capacitance–voltage profiler (ECV) measurements, the emitter formed using a POCl₃ flow rate of 1000 sccm contained the least amount of inactive dopant and resulted in reasonable performance in the silicon solar cell. As the POCl₃ flow rate increased, the doped silicon wafer included electrically inactive P near the surface, which functions as a defect degrading the electrical performance of the emitter. As a result of this, the removal of the dead layer containing the inactive P was attempted through dipping the doped wafer in a HF solution. After this process, the emitter saturation current density and implied V_oc were improved. The completed solar cells and their external quantum efficiencies at a short wavelength also demonstrated improved performance. A quantitative analysis of the emitter can provide a deeper understanding of methods to improve the electrical characteristics of the silicon solar cell.     

Photoreflectance study on the photovoltaic effect in InAs/GaAs quantum dot solar cell

To investigate the effect of quantum dot (QD) layers on the photovoltaic process of InAs/GaAs QD solar cell (QDSC), QD layers were embedded in conventional GaAs p-n junction SC (GaAs SC) structures. The photoreflectance (PR) was examined at different temperatures (T) and excitation light intensities (I_ex) to investigate the photovoltaic effects through observation of the Franz-Keldysh oscillations (FKOs) in the PR spectra. The evaluated the p-n junction electric fields (F_pn) of the InAs QDSC was different from that of the GaAs SC. Moreover, InAs QDSC show that the different photovoltaic behaviors compared with GaAs SC by varying I_ex and T. From these considerations, we suggest that the different photovoltaic behaviors are caused by the effect of the additional photo-carrier generation in InAs QD layers resulting in enhancement of the field screening effect in F_pn.     

选择性发射极晶体硅太阳电池的二维器件模拟及性能优化

利用PC2D二维模拟软件对选择性发射极晶体硅太阳电池(SE电池)进行了器件模拟和参数优化的研究.在对丝网印刷磷浆法制备的SE电池的实测典型电流-电压曲线实现完美拟合的基础上,全面系统地研究了栅线、基区、选择性发射区和背表面场层等的参数对电池性能的影响.模拟表明:基区少子寿命、前表面复合速度和背表面复合速度是对电池效率影响幅度最大的三个参数.在所研究的参数范围内,当基区少子寿命从50μs上升到600μs时,电池效率从18.53%上升到19.27%.低的前表面复合速度是使发射区方块电阻配比优化有意义的前提.要取得理想的电池效率,背表面复合速度需控制在500 cm/s以下.此外,对于不同的前表面复合速度,电池效率的最大值总是在50—90Ω/□的重掺区方阻、110—180Ω/□的轻掺区方阻的范围内取得.对不同的栅线数目,重掺区宽度与栅线间距之比为32%时,电池的效率最高.另外,在主栅结构保持较低面积比率的前提下,主栅数目的增加也可提高效率.最后,通过优化p型SE电池的效率可达到20.45%.     

双面HIT太阳电池TCO与非晶硅界面势垒的模拟优化

采用美国滨州大学研发的AMPS-1D软件,模拟了TCO与非晶硅界面势垒对TCO/a-Si:H(p+)/a-Si:H(i)/c-Si(n)/a-Si:H(i) /a-Si:H(n+)/TCO双面HIT异质结太阳电池光伏特性的影响.结果表明太阳电池的TCO/p+前接触界面势垒(对于电子)越高,越易形成欧姆接触,且电池的短波响应增强,使电池性能变好.模拟还发现,n+/TCO背接触界面势垒(对于电子)越低,电池性能越好.若背场重掺杂,在背接触势垒小于等于0.5 eV时,电池的转换效率不会受到背接触势垒的影响;若背场低掺杂,在背接触势垒很小的情况下,也能达到与重掺杂相同的转换效率.     

High-efficient Schottky-junction silicon solar cell using silver nanowires covering nitrogen-doped amorphous carbon

Synthesized graphene (Gr) on metal substrates that requires additional surface-to-surface transfer procedure to form Gr-on-silicon (Gr-Si) Schottky-junction configuration, which in turn results in the photovoltaic degradation caused by both mechanical damages and chemical contaminations during several wet chemical steps. This current issue has motivated us to develop alternative Schottky-junction configuration using silver nanowires (AgNWs) covering nitrogen (N)-doped amorphous carbon (a-C) films annealed in the temperature range 750–900 °C. Compared to the Schottky-junction Si solar cell based on 900 °C annealed N-doped a-C films (C_N-900-Si) with only Ag grid, all of AgNWs-C_N-900-Si solar cells exhibit the significant enhancement of photovoltaic characteristics. Consequently, the remarkable power conversion efficiency (PCE) of 6.17% is achieved on 0.2 wt% AgNWs-C_N-900-Si solar cell, which is far superior to that of the C_N-900-Si solar cell with only Ag grid (~0.13%). Furthermore, the 0.2 wt% AgNWs-C_N-900-SiNWs solar cell shows the highest short-circuit current density (J_SC) of 23.42 mA/cm² and PCE of 7.67%, which is a PCE enhancement of ~24% when compared to the 0.2 wt% AgNWs-C_N-900-Si solar cell. This study demonstrates that AgNWs network can accelerate the charge carrier extraction from Schottky-contact between C_N-900 and n-Si substrate, leading to greatly reduced series resistance that results in significantly enhanced photovoltaic characteristics.     

多晶硅中的氧碳行为及其对太阳电池转换效率的影响

认识及控制多晶硅中杂质行为对于实现低成本、高效率多晶硅太阳电池有着重要的意义.利用红外光谱技术研究了定向凝固多晶硅锭中不同部位材料热处理前后的氧浓度、碳浓度变化,结合少子寿命、光电转换效率、内量子效率等电池性能,探索不同含量的氧、碳杂质对电池性能影响的物理机制.提出一种考虑碳影响的氧沉淀生长模型,并模拟了热处理后氧沉淀的尺寸分布和数量.研究发现,碳除了使利用硅锭顶部材料制备得到的电池转换效率降低外,还是决定氧沉淀作用的重要因素.由于碳含量多造成中部材料氧沉淀的尺寸大、数量多,引起缺陷,增加复合,而碳在底部 关键词： 氧 碳 太阳电池 转换效率     

Double-layer indium doped zinc oxide for silicon thin-film solar cell prepared by ultrasonic spray pyrolysis

Indium doped zinc oxide(ZnO:In) thin films were prepared by ultrasonic spray pyrolysis on corning eagle 2000 glass substrate.1 and 2 at.% indium doped single-layer ZnO:In thin films with different amounts of acetic acid added in the initial solution were fabricated.The 1 at.% indium doped single-layers have triangle grains.The 2 at.% indium doped single-layer with 0.18 acetic acid adding has the resistivity of 6.82×10-3Ω·cm and particle grains.The doublelayers structure is designed to fabricate the ZnO:In thin film with low resistivity(2.58×10-3Ω·cm) and good surface morphology.It is found that the surface morphology of the double-layer ZnO:In film strongly depends on the substratelayer,and the second-layer plays a large part in the resistivity of the double-layer ZnO:In thin film.Both total and direct transmittances of the double-layer ZnO:In film are above 80% in the visible light region.Single junction a-Si:H solar cell based on the double-layer ZnO:In as front electrode is also investigated.     

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     

非晶/微晶两相硅薄膜电池的计算机模拟

在对不同晶相比硅薄膜的实验研究的基础上，利用有效介质理论估算了这种两相材料的光吸 收系数、迁移率寿命乘积及带隙宽度等参量，计算机模拟了不同结晶比硅薄膜电池的伏安特 性及光谱响应；结果为随着本征层微晶成分的增多，电池的开路电压逐渐减小，短路电流逐 渐增大，本征层的最佳厚度逐渐增大，填充因子有降低的趋势，电池的效率随晶相比的增大 而减小. 电池的光谱响应曲线表明，随晶相比的增大电池的长波响应明显提高. 根据这些模 拟结果，分析讨论了在考虑Lambertian背反射的情况下，非晶/微晶叠层电池的底电池采用 晶相比为40％—50％的两相硅薄膜材料做本征层是最佳选择. 关键词： 两相硅薄膜 太阳能电池 计算机模拟     

磁场对聚合物光电池中电流的影响

制备了结构为 ITO/PEDOT:PSS/P3HT:PCBM/Ca/Al的聚合物光电池器件,并在不同偏压下,分别测量了器件的光电流和暗电流随外加磁场的变化. 发现随外加磁场增加,光电流增强,暗电流减弱. 从聚合物光电池中光电流和暗电流的产生机制出发,对该现象进行了解释,认为外加磁场可以有效改变单重态极化子对和三重态极化子对之间的相对比例,进而使自由载流子浓度增加. 光生自由载流子浓度增加是光生电流增强的原因,而自由载流子与三重态激子的相互作用导致了暗电流减弱. 开路电压附近,光电流随磁场增加而增强可以近似 关键词： 聚合物光电池 磁场效应 光生电流 极化子对     

太阳能电池在微生物燃料电池中的光电催化性能研究

微生物燃料电池（microbialfuelcell,MFC）是利用电化学技术将微生物代谢能转化为电能并可同时降解废水的一种装置．本文针对目前MFC输出功率密度小、工作效率低等缺点,提出了利用半导体光催化和微生物催化协同作用构建新型MFC体系的设想,即将半导体太阳能电池串入MFC体系,组成“光电池．微生物电池”新型电池体系．实验结果表明,在光照的作用下,新型MFC体系的开路电压、短路电流和最大输出功率密度,与普通MFC体系相比,均有了明显的提高．光电催化作用的引入,有效地改善了MFC体系阴极的接受电子的能力,使阳极提供电子的能力得到最大限度的发挥,既给MFC体系的运转提供了一部分动力,也为MFC体系提高污染物的降解速率提供了基础．此项研究对解决能源危机和环境污染具有重要意义．     

Comparison of D.C. and A.C. electro-analytical methods for measuring diode ideality factors and series resistances of silicon solar cells

The diode ideality factor (m) and the series resistance (R_s) of a Si solar cell represent two critical performance-indicator parameters of the device. Since both m and R_s are functions of voltage (V) and temperature (T), simultaneous electrical measurements of these parameters under variable conditions of V and T can often be difficult with traditional direct current (D.C.) techniques. Using the electro-analytical method of linear sweep voltammetry (LSV) and a commonly available Si solar cell, we explore these specific confines of such D.C. measurements. The results are compared with those obtained from a parallel set of alternating current (A.C.) measurements using impedance spectroscopy (IS). LSV provides the main D.C. parameters (open circuit voltage, short circuit current, fill factor, and efficiency) of the cell, but is limited in terms of independently measuring m and R_s beyond strong forward biased conditions. The IS approach is free of the latter experimental constraints, and at the same time can provide several other important electrical parameters of the solar cell. Specifically, IS detects the presence of a low-high (p–p⁺) junction at the back surface of the cell, and serves as an efficient probe of certain electrical characteristics of this junction.     

Investigation on antireflection coatings for Al:ZnO in silicon thin-film solar cells

We numerically investigate the role of antireflection (AR) coatings, composed of SiO₂ and/or ZnO, in suppression of interfacial reflections in the presence of the transparent conducting oxide, Al-doped ZnO (AZO). Three structures are simulated: (a) AR coatings in organic light-emitting diodes (OLEDs) and flat panel displays, (b) AR coating located between the glass and the AZO, and (c) same as the case b except the involvement of another AR coating between the AZO and the amorphous silicon layers. The weighted average transmittance according to the AM1.5 solar spectrum, the photovoltaic transmittance (T_pv), suggests that there is no evident difference between the structures a and b, especially when the layer number of AR coatings is less than three. An effective way to improve T_pv is presented in the structure c, where T_pv is increased from 73.54% to 76.32% with a three-layered AR coating located between AZO and a-Si. It implies that the suppression of interfacial reflections, resulting from the considerable mismatch of refractive indices at the interface of AZO and a-Si, would benefit the efficiency improvement of silicon thin-film solar cells.     

钙钛矿/硅异质结叠层太阳电池:光学模拟的研究进展

近几年,钙钛矿/硅异质结叠层太阳电池发展迅速,效率已经从13.7％提升到29.1％.由于叠层电池器件的制作工艺复杂,而叠层太阳电池中的光学损失对转换效率的影响很大,所以通过光学模拟进而获得高效电池至关重要.本文首先从商业软件和自建模型两方面概述了光学模拟的方法,接着从反射损失和寄生吸收两方面针对光学模拟研究进展进行了总...     

微晶硅锗太阳电池本征层纵向结构的优化

采用射频等离子体增强化学气相沉积技术, 研究了辉光功率对微晶硅锗材料结构特性和光电特性的影响, 提出使用功率梯度的方法制备微晶硅锗薄膜太阳电池本征层. 优化后的微晶硅锗本征层不仅保持了晶化率纵向分布的均匀性, 而且形成了沿生长方向由宽到窄的渐变带隙分布, 使电池的填充因子和短路电流密度都得到了提高. 采用此方法制备的非晶硅/微晶硅锗双结叠层电池转换效率达到了9.54%.