a-Si/c-Si异质结结构太阳能电池设计分析

通过应用 Scharfetter- Gum mel解法数值求解 Poisson方程 ,对热平衡态 a- Si/ c- Si异质结太阳能电池进行计算机数值模拟分析 ,着重阐述在 a- Si/ c- Si异质结太阳能电池中嵌入 i( a- Si:H)缓冲薄层的作用 ,指出采用嵌入 i( a- Si:H )缓冲薄层设计能有效增强光生载流子的传输与收集 ,从而提高 a- Si/ c- Si异质结太阳能电池的性能 ,同时还讨论 p+ ( a- Si:H)薄膜厚度和 p型掺杂浓度对光生载流子传输与收集的影响 ,而高强度光照射下模拟计算表明 ,a- Si/ c- Si异质结结构太阳能电池具有较高光稳定性     

Porous silicon in crystalline silicon solar cells: a review and the effect on the internal quantum efficiency

Crystalline silicon (c-Si) is the dominant semiconductor material in use for terrestrial photovoltaic cells and a clear tendency towards thinner, active cell structures and simplified processing schemes is observable within contemporary c-Si photovoltaic research. The potential applications of porous silicon and related benefits are reviewed. Specific attention is given to the different porous silicon formation processes, the use of this porous material as anti-reflection coating in simplified processing schemes and for simple selective emitter processes and its light trapping and surface passivating capabilities, which are required for advantageous use in thin active cell structures. Our analysis of internal quantum efficiency data obtained on both conventional and thin-film c-Si solar cells has been performed with the aim of describing the light diffusing behaviour of porous Si as well as investigating the surface passivating capabilities. An effective entrance angle of 60° is derived, which corresponds to totally diffuse isotropic light, and the importance of a correction for absorption losses in the porous layer is illustrated. Furthermore, photoconductivity decay measurements of freshly etched porous Si on float-zone p-type Si indicate a strong bias-light dependency and a fast degradation of the surface recombination velocity. © 1998 John Wiley & Sons, Ltd.     

异质结硅太阳能电池a—Si：H薄膜的研究

通过应用Scharfetter-Gummel数值求解Poisson方程，对热平衡态P^ （a-Si:H)/n(c-Si)异质结太阳能电池进行计算机数值模拟分析。结果指出，采用更薄P^ (a-Si：H）薄膜设计能有效增强光生载流子的传输与收集，从而提高a-Si/c-Si异质结太阳能电池的性能。同时，还讨论了P^ (a-Si:h)薄膜中P型掺杂浓度对光生载流了传输与收集的影响。高强茺光照射下模拟，计算表明，a-Si/c-Si异质结结构太阳能电池具有较高光稳定性。     

等离子体过程不稳定性和氢处理对HIT电池界面特性影响的研究

采用等离子体增强化学气相沉积（PECVD）技术制备薄膜硅/晶体硅异质结,通过测量沉积了本征非晶硅（a-Si:H(i)）后晶体硅（c-Si）的少子寿命以及结构为Ag/a-Si:H(p)/a-Si:H(i)/c-Si(n) /Ag 异质结的暗I-V特性,研究了等离子体初期瞬态过程和氢预处理对异质结界面性质的影响。结果表明：使用挡板且当挡板时间（tS）大于100秒时,可以有效地减少等离子体初期瞬态过程对界面性质的负面影响;与热丝化学气相沉积中氢原子处理有利于界面钝化不同,PECVD中的氢等离子体处理,由于氢原子的轰击特性,对钝化可能存在一定的不利影响;最优氢预处理时间为60秒。     

硅薄膜太阳电池抗反射微纳结构研究

在硅薄膜太阳电池中,灵活的光学设计可以实现表层的零反射损耗,增大吸收层中光的透射率,从而提高薄膜太阳电池的光收集能力。在薄膜太阳电池吸收层表面设计了矩形介质光栅。利用严格耦合波理论和模态传输理论研究了光栅结构参数对反射率的影响。考虑到AM1.5 G太阳能光谱和a-Si的吸收光谱,光栅参数进一步优化。由于微加工的误差,使得矩形光栅变成梯形光栅,必然会影响硅薄膜太阳电池表面反射率。研究结果表明,长周期光栅同样可以实现低反射率,在工艺上也容易实现。采用梯形光栅可进一步降低表面反射率,并且在太阳光入射角为-40°~+40°的范围内保持在6%以下。     

Silicide application on gated single-crystal, polycrystalline andamorphous silicon FEAs. I. Mo silicide

In order to improve both the level and the stability of electron field emission, the tip surface of silicon field emitters have been coated with a molybdenum layer of thickness 25 nm through the gate opening and annealed rapidly at 1000°C in inert gas ambient. The gate voltages of single-crystal silicon (c-Si), polycrystalline silicon (poly-Si) and amorphous silicon (a-Si) field emitter arrays (FEAs) required to obtain anode current of 10 nA per tip are 90 V, 69 V, and 84 V, respectively. In the case of the silicide emitters based on c-Si, poly-Si and a-Si, these gate voltages are 76 V, 63 V, and 69 V, respectively. Compared with c-Si, poly Si and a-Si field emitters, the application of Mo silicide on the same silicon field emitters exhibited 9.6 times, 2.1 times, and 4.2 times higher maximum emission current, and 6.1 times, 3.7 times, and 3.1 times lower current fluctuation, respectively. Moreover, the emission currents of the silicide FEAs depending on vacuum level are almost same in the range of 10^-9~10^-6 torr. This result shows that silicide is robust in terms of anode current degradation due to the absorption of air molecules     

Optimization of n/i and i/p buffer layers in n-i-p hydrogenated microcrystalline silicon solar cells

Hydrogenated microcrystalline silicon (μc-Si:H) intrinsic films and solar cells with n-i-p configuration were prepared by plasma enhanced chemical vapor deposition (PECVD). The influence of n/i and i/p buffer layerson the μc-Si:H cell performance was studied in detail. The experimental results demonstrated that the efficiency is much improved when there is a higher crystallinity at n/i interface and an optimized a-Si:H buffer layer at i/p interface. By combining the above methods, the performance ofμc-Si:H single-junction and a-Si:H/μc-Si:H tandemsolar ceils has been significantly improved.     

非晶硅顶电池中的n型掺杂层对非晶硅/微晶硅叠层太阳电池性能的影响

采用超高频等离子增强化学气相沉积(VHF-PECVD)技术,逐次高速沉积非品硅顶电池及微晶硅底电池,形成pin/pin型非晶硅/微晶硅叠层电池.通常顶电池的n层与底电池的P层均采用微晶硅材料来形成隧穿复合结,然而该叠层电池的光谱响应测试结果表明,顶电池存在着明显的漏电现象.针对该问题作者提出,在顶电池的微品硅n层中引入非晶硅n保护层的方法.实验结果表明,非晶硅n层的引入有效地改善了顶电池漏电的现象;在非晶硅n层的厚度为6nm时,顶电池的漏电现象消失,叠层电池的开路电压由原来的1.27提高到1.33V,填允因子由60%提高剑63%.     

A life cycle assessment of perovskite/silicon tandem solar cells

Given the rapid progress in perovskite solar cells in recent years, perovskite/silicon (Si) tandem structure has been proposed to be a potentially cost‐effective improvement on Si solar cells because of its higher efficiency at a minimal additional cost. As part of the evaluation, it is important to conduct a life cycle assessment on such technology in order to guide research efforts towards cell designs with minimum environmental impacts. Here, we carry out a life cycle assessment to assess global warming, human toxicity, freshwater eutrophication and ecotoxicity and abiotic depletion potential impacts and energy payback time associated with three perovskite/Si tandem cell structures using silver (Ag), gold (Au) and aluminium (Al) as top electrodes compared with p–n junction and hetero‐junction with intrinsic inverted layer Si solar cells. It was found that the replacement of the metal electrode with indium tin oxide/metal grid in the tandem cell reduces the environmental impacts significantly compared with the perovskite cell. For all the impacts assessed, we conclude that the perovskite/Si tandem using Al as top electrode has better environmental outcomes, including energy payback time, when compared with the other tandem structures studied. Use of Al in preference to noble metals for contacts, Si p–n junction in preference to intrinsic inverted layer and the avoidance of 2,20,7,70‐tetrakis(N ,N‐di‐p‐methoxyphenylamine)9,90‐spirobifluorene (Spiro‐OMeTAD) are environmentally beneficial. The key result found of this work is that the most important factor for the better environmental impacts of these tandem solar cells is the transparency and electrical conductivity of the perovskite layer after it fails. Copyright © 2017 John Wiley & Sons, Ltd.     

A high-performance thin-film transistor with a vertical offsetstructure

In this study, we propose a novel device structure combined with conventional hydrogenated amorphous silicon (a-Si:H) for the source and drain regions and microcrystalline silicon (μc-Si:H) for the channel region to obtain a high-performance thin-film transistor (TFT). This is a vertical a-Si:H offset structure used to suppress OFF-state current to a small value which is comparable to the conventional a-Si:H TFTs with a much higher drivability. The fabrication process is simple, low temperature (⩽300°C), and low cost, with a potential for high reliability     

标准测试条件下人造太阳光源的谱失配及影响

标准测试条件下,人造太阳光源的光谱形式、辐 照强度、光谱失配因子等是影响太 阳电池器件测试结果准确性的重要因素。本文以标准太阳光谱AM1.5 为参考,从光谱失配角 度,计算和分析了4种常用人造太阳光源(Arc lamp灯、Q-Flash灯、Q-Flash W灯和ELH 灯)与标准太阳光谱AM1.5之间的光谱失配因子的变化和这四种人造 太阳光源辐照下晶硅电 池的输出参数的变化。计算结果表明:Arc lamp型人造太阳光源的光谱失配因子为 0.979, 晶硅电池输出参数最接近标准太阳光谱AM1.5辐照下的输出参数 ;因光谱失配影响,4种不同人造太阳光源辐照下晶硅电池的输出参数较标准太阳光谱AM1.5辐照下的输出 参数会发生明显变化。     

MXene-Interconnected Two-Terminal,Mechanically-Stacked Perovskite/Silicon Tandem Solar Cell with High Efficiency

Two-terminal, mechanically-stacked perovskite/silicon tandem solar cells offer a feasible way to achieve power conversion efficiencies (PCEs) of over 35%, provided that the state-of-the-art industrial silicon solar cells and perovskite solar cells (PSCs) are fully compatible with one another. Herein, two-terminal, mechanically-stacked perovskite/silicon tandem solar cells are developed by mechanically interconnecting semitransparent PSCs and TOPCon solar cells with a MXene interlayer. The semitransparent PSCs are made from wide-bandgap perovskite Cs_0.15FA_0.65MA_0.20Pb(I_0.80Br_0.20)₃ films. Furthermore, the co-additives KPF₆ and CH₃NH₃Cl(MACl) are employed to reduce grain boundaries and intragranular defects in the perovskite, boosting the PCE of the semitransparent PSCs to a record-high value of 20.96% under reverse scan (RS) through a reduction in non-radiative recombination probability. These optimized semitransparent PSCs are then employed in MXene-interconnected two-terminal, mechanically-stacked tandem solar cells. The enhanced interfacial carrier transportation, with minimal influence on light transmission, imparted by the MXene flakes allows the tandem solar cells to achieve a stabilized PCE of 29.65%. The tandem cells also exhibit acceptable operational stability and are able to retain ≈93% and 92% of their initial PCEs after 120 min of continuous illumination or storage in ambient air for 1000 h, respectively.     

Short‐circuit current of solar cells under artificial light

A model to estimate the short‐circuit current of a solar cell under artificial light from the short‐circuit current of the same solar cell under AM1.5 1 kW/m² is described. The results may help designers of solar‐powered portable equipment and consumer products working indoors or under a mixture of artificial and sunlight. It is concluded that the ratio of the short‐circuit currents of the same solar cell generated under fluorescent light of 1 lux illuminance divided by the short‐circuit current generated under standard 1 Sun AM1.5 conditions is around 3 × 10⁻⁶ for typical crystalline silicon and CIS solar cells. This value is one order of magnitude greater if the light source considered is an incandescent lamp. In the case of amorphous silicon solar cells the value of the ratio is close to 8 × 10⁻⁶ either for fluorescent or incandescent lamps. CdTe solar cells are also considered, and this factor is about 4 × 10⁻⁶ under fluorescent light, and four times bigger when an incandescent lamp is used. Some measurements performed validate the figures obtained. Copyright © 2002 John Wiley & Sons, Ltd.     

Thermal stability of cobalt and nickel silicides

Thermal stability of cobalt and nickel silicides on crystalline Si (c-Si) and amorphous Si (a-Si) has been investigated. We have found that CoSi₂ is thermally stable on a-Si and c-Si substrates up to 950°C for 30 min. NiSi is stable and shows low resistivity on c-Si at around 700°C for 30 min, but is unstable on a-Si substrate even after annealing at 400°C.     

Power Conversion Efficiencies of Perovskite and Dye-Sensitized Solar Cells under Various Solar Radiation Intensities

Semiconductors - We present the results of a comparative study on behaviour of the photovoltaic parameters in perovskite (PSC), dye-sensitized (DSC) and crystalline silicon (c-Si) solar cells under...     

An a-Si:H/a-Si,Ge:H bulk barrier phototransistor with a-SiC:Hbarrier enhancement layer for high-gain IR optical detector

The design and fabrication of a high-gain amorphous silicon/amorphous silicon germanium (a-Si:H/a-Si,Ge:H) bulk barrier phototransistor for infrared light detection applications are reported. The a-Si,Ge:H material featured a lower energy gap and is suitable for the absorption of longer wave light, but it also leads to a low breakdown voltage and high dark current. An additional a-SiC:H thin-film layer was used at the collector/base interface in the conventional amorphous bulk barrier phototransistor to enhance the function of the bulk barrier and obtain high optical gain     

Simulation analysis of a high efficiency GaInP/Si multijunction solar cell

The solar power conversion efficiency of a gallium indium phosphide(GaInP)/silicon(Si)tandem solar cell has been investigated by means of a physical device simulator considering both mechanically stacked and monolithic structures.In particular,to interconnect the bottom and top sub-cells of the monolithic tandem,a gallium arsenide(GaAs)-based tunnel-junction,i.e.GaAs(n+)/GaAs(p+),which assures a low electrical resistance and an optically low-loss connection,has been considered.The J–V characteristics of the single junction cells,monolithic tandem,and mechanically stacked structure have been calculated extracting the main photovoltaic parameters.An analysis of the tunnel-junction behaviour has been also developed.The mechanically stacked cell achieves an efficiency of 24.27%whereas the monolithic tandem reaches an efficiency of 31.11%under AM1.5 spectral conditions.External quantum efficiency simulations have evaluated the useful wavelength range.The results and discussion could be helpful in designing high efficiency monolithic multijunction GaInP/Si solar cells involving a thin GaAs(n+)/GaAs(p+)tunnel junction.     

Two-Terminal Tandem Solar Cells DSC/<Emphasis Type="Italic">c</Emphasis>-Si: Optimization of TiO<Subscript>2</Subscript>-based Photoelectrode Parameters

New types of two-terminal tandem solar cells DSC/c-Si in which mesoscopic dye-sensitized solar cell (DSC) was connected in parallel with a crystalline silicon (c-Si) solar cell, were developed and investigated. We have measured the optical and photovoltaic parameters for both the individual and the fabricated tandem DSC/c-Si solar cells. It was shown that the highest efficiency of 14.7% for the tandem DSC/c-Si solar cell under standard AM1.5G (100 mW/cm²) illumination conditions was achieved for DSC based on 3.5 μm thick titanium dioxide photoelectrode.     

Surface morphology and I-V characteristics of single-crystal,polycrystalline, and amorphous silicon FEA's

This letter reports the surface morphology and current-voltage (I-V) characteristics of single-crystal silicon (c-Si), polycrystalline silicon (poly-Si), and amorphous silicon (a-Si) field emitter arrays (FEAs). As-deposited a-Si film has a smoother surface than poly-Si film. The surface morphology of the a-Si remains smooth even after phosphorus doping and oxidation at 950°C to be improved in emission characteristics, i.e., smaller anode current deviation among arrays smaller gate current, and higher failure voltage than those of poly-Si FEAs. Such improved characteristics can be explained by the smooth surface morphology which is kept during doping and oxidation. The surface roughness and emission characteristics of a-Si FEAs are comparable to those of c-Si FEAs     

引入微晶硅底电池的PIN型三结Si基薄膜太阳电池的制备

为充分利用太阳光谱能量,在玻璃衬底的PIN型a-Si/a-SiGe电池中直接引入了微晶硅(μc-Si:H)底电池.从透明导电氧化物(TCO)衬底的光透过率估算了PIN型a-Si:H/a-SiGe:H/μc-Si:H三结电池实现高转化效率的可行性.通过调整μc-Si:H底电池厚度考察三结电池的性能变化,结果发现,受中间电...