Your search keyword '"back-contact"' showing total 61 results

1. Comparative analysis of half-cell and full-cell PV commercial modules for sustainable mobility applications: Outdoor performance evaluation under partial shading conditions

Author

Cabrera-Tobar, Ana, Dolara, Alberto, Leva, Sonia, Mazzeo, Domenico, and Ogliari, Emanuele

Published

2024

2. The Impact of Interfacial Recombination on Hysteresis in Back-Contact Perovskite Solar Cells.

Author

Tian, Peidong, Chang, Yanyan, Lu, Shulong, and Ji, Lian

Subjects

CARRIER density, SOLAR cells, ELECTRIC potential, OPEN-circuit voltage, SHORT-circuit currents

Abstract

A back-contact perovskite solar cell (BC-PSC) has been simulated. The J–V curves were calculated with different degrees of the interfacial recombination, and the characteristics of basic physical phenomena inside the device, including carrier concentration distribution, ion concentration distribution, electric potential change, and carrier recombination rate, have also been investigated. It was found that the effect of the perovskite layer's upper surface (US) interfacial recombination on the hysteresis phenomenon is greater than that of the perovskite layer's lower surface (LS) interfacial recombination. In addition, it has been found that the inverted hysteresis phenomenon occurs in the BC-PSC with the LS interfacial recombination. Moreover, the hysteresis loops corresponding to the US interfacial recombination of the perovskite layer were close to the short-circuit current side, and the hysteresis loops corresponding to the LS interfacial recombination of the perovskite layer were close to the open-circuit voltage side. These results indicate that both of the US and LS interface recombinations in the BC-PSC play a crucial role in the hysteresis phenomenon. [ABSTRACT FROM AUTHOR]

Published

2024

3. Back-contact configuration energizes perovskite photovoltaic modules

Author

Xiaoyu Yang, Yongguang Tu, Fengjun Ye, and Zheng Bao

Subjects

perovskite solar cell, back-contact, photovoltaic technology, device configuration, Chemistry, QD1-999, Physics, QC1-999

Abstract

In this viewpoint, recent hot topics in the photovoltaic community, interdigitated back contact (IBC) cells, are systematically reviewed from the view of device configuration. Two categories of IBC designs on the most popular perovskite solar cells (PSCs) were discussed, and a planar back-contact perovskite module was first proposed. The device configuration, fabrication methods, working mechanism, optimization strategies, and future development directions of this novel PSC module were put forward to show its superiorities in the module performance, processing difficulty, and extensible functionality among present perovskite modules, presenting promising potential to improve the competitiveness of perovskite technology in the photovoltaic market.

Published

2024

4. Nanoimprint Lithography as a Route to Nanoscale Back-Contact Perovskite Solar Cells.

Author

Harwell, Jonathon and Samuel, Ifor D. W.

Abstract

Back-contact perovskite solar cells are of great interest because they could achieve higher performance than conventional designs while also eliminating the need for transparent conductors. Current research in this field has focused on making electrode structures with reduced widths to collect charges more efficiently, but current lift-off-based fabrication techniques have struggled to achieve electrode widths smaller than 1000 nm and are difficult to implement on large areas. We demonstrate nanoimprint lithography in an etch-down procedure as a simple and easily scalable method to produce honeycomb-shaped, quasi-interdigitated electrode structures with widths as small as 230 nm. We then use electrodeposition to selectively deposit conformal coatings of a range of different hole-selective layers and explore how the efficiency of back-contact perovskite solar cells changes as the feature sizes are pushed into the nanoscale. We find that the efficiency of the resulting devices remains almost unchanged as the electrode width is varied from 230 to 2000 nm, which differs from reported device simulations. Our results suggest that reducing recombination and improving the quality of the charge transport layers, rather than reducing the minimum feature size, are likely to be the best pathway to maximizing the performance of back-contact perovskite solar cells. [ABSTRACT FROM AUTHOR]

Published

2023

5. Ideality Factor Mapping of Back‐Contact Perovskite Solar Cells.

Author

Rietwyk, Kevin J., Lin, Xiongfeng, Tan, Boer, Warnakula, Tharindu, Holzhey, Philippe, Zhao, Boya, Deng, Siqi, Surmiak, Maciej A., Jasieniak, Jacek, and Bach, Udo

Subjects

*SOLAR cells, *PHOTOVOLTAIC power systems, *PEROVSKITE, *ELECTRON transport, *OPEN-circuit voltage, *LOW voltage systems

Abstract

The efficiency of back‐contact perovskite solar cells has steadily increased over the past few years and now exceeds 11%, with interest in these devices shifting from proof‐of‐concept to viable technology. In order to make further improvements in the efficiency of these devices it is necessary to understand the cause of the low fill factor, low open‐circuit voltage (VOC), and severe hysteresis. Here a time‐dependent Suns‐Voc and Suns‐photoluminescence (PL) analysis are performed to monitor the transient ideality factor spatially. Two sets of quasi‐interdigitated back‐contact perovskite solar cells are studied; cells with and without a mesoporous TiO2 layer. Maps of the PL intensity and ideality factor resemble the periodic structure of the back‐contact electrodes and the transient behavior exhibit distinct features such as a temporary variation in the periodicity of the modulation, spatial phase shifting, and phase offsets. It is shown that the presence of the mesoporous layer greatly reduces recombination, increasing the VOC by 0.12 V. Coupled 2D time‐dependent drift‐diffusion simulations allow the experimental results to be modeled, and replicate the key features observed experimentally. They reveal that non‐uniform ion distribution along the transport layer interfaces can drastically alter the PL intensity and ideality factor throughout the device. [ABSTRACT FROM AUTHOR]

Published

2023

6. Slot-Die-Coated Active Layer for Printed Flexible Back-Contact Perovskite Solar Cells.

Author

Parkhomenko, Hryhorii P., Mangrulkar, Mayuribala, and Jumabekov, Askhat N.

Subjects

SOLAR cells, PRINTED electronics, FLEXIBLE electronics, POLYMER electrodes, SANDWICH construction (Materials), PEROVSKITE

Abstract

Perovskites have already shown potential as active layers in photovoltaic applications. Furthermore, a low-cost and simple solution processing technology allows perovskites to be used in flexible and printed electronics. Perovskite solar cells (PSC) with a back-contact (BC) structure, in which the electrode system is based on a quasi-interdigitated back-contact (QIBC) design, promise to increase the power conversion efficiency (PCE) of devices beyond those that can be obtained using PSCs with a traditional sandwich structure. While the spin-coating technique is used to deposit the perovskite layer of lab-scale BC PSCs, the application of large-area printing techniques to deposit the perovskite layer of such devices is yet to be explored. Therefore, this work demonstrates an application of the slot-die coating technique to print the perovskite active layer of BC PSCs with QIBC electrodes on flexible polymer substrates. The morphology of the obtained perovskite films on QIBC electrodes are investigated and the primary photoelectric parameters of the resulting BC PSCs are measured. The charge carrier recombination processes in the fabricated BC PSCs are investigated and the dominant mechanism for carrier loss in the devices is determined. The findings of the work give an insight into the properties of the slot-die-coated perovskite active layer of BC PSCs and points to exciting new research opportunities in this direction. [ABSTRACT FROM AUTHOR]

Published

2023

7. Investigation of the Emerging Materials Based High-Efficiency CdTe Solar Cell.

Author

Shabir, Aamar and Ullah, Muhammad

Subjects

SOLAR cells, RENEWABLE energy sources, FOSSIL fuels, CADMIUM telluride, COST effectiveness

Abstract

Solar light is a renewable source of energy with no bad impact on the environment. It can compensate for energy taken from non-renewable energy sources like petroleum, and fossil fuels. The fabrication of solar cells passed through several steps from 1st generation to modern nano-material-based solar cells. One of the good solar cells is known as the cadmium telluride (CdTe) solar cell which has good efficiency. Thin-film CdTe has been considered the best choice for the development of cost-effective and reliable solar cells. Efficiency has been achieved as high as 23.5% in CdTe cells in the lab in 2020, and the present techniques for CdTe solar cells stepped towards commercialization. This work will investigate the development of the CdTe solar cell in a systematic way that includes its fabrication process, back contact selection, parameters impacts, and structural modification which directly impact improving the efficiency of the solar cell. In the end, this work will discuss a brief comparison of the improved efficiency with other solar cells and its future aspects. [ABSTRACT FROM AUTHOR]

Published

2022

8. Fabrication of Flexible Quasi-Interdigitated Back-Contact Perovskite Solar Cells.

Author

Parkhomenko, Hryhorii P., Shalenov, Erik O., Umatova, Zarina, Dzhumagulova, Karlygash N., and Jumabekov, Askhat N.

Subjects

*SOLAR cells, *PEROVSKITE, *OPEN-circuit voltage, *OPTOELECTRONIC devices, *SURFACE recombination, *PHOTOVOLTAIC power systems

Abstract

Perovskites are a promising class of semiconductor materials, which are being studied intensively for their applications in emerging new flexible optoelectronic devices. In this paper, device manufacturing and characterization of quasi-interdigitated back-contact perovskite solar cells fabricated on flexible substrates are studied. The photovoltaic parameters of the prepared flexible quasi-interdigitated back-contact perovskite solar cells (FQIBC PSCs) are obtained for the front- and rear-side illumination options. The dependences of the device's open-circuit potential and short-circuit current on the illumination intensity are investigated to determine the main recombination pathways in the devices. Spectral response analysis of the devices demonstrates that the optical transmission losses can be minimized when FQIBC PSCs are illuminated from the front-side. Optoelectronic simulations are used to rationalize the experimental results. It is determined that the obtained FQIBC PSCs have high surface recombination losses, which hinder the device performance. The findings demonstrate a process for the fabrication of flexible back-contact PSCs and provide some directions for device performance improvements. [ABSTRACT FROM AUTHOR]

Published

2022

9. Cross-Sectional Conductive Atomic Force Microscopy of CdTe/CdS Solar Cells: Effects of Etching and Back-Contact Processes; Preprint

Author

Al-Jassim, M

Published

2006

10. Parametric optimization of back-contact T-C-O-free dye-sensitized solar cells employing indoline and porphyrin sensitizer based on cobalt redox electrolyte.

Author

Molla, Md. Zaman, Baranwal, Ajay Kumar, Kapil, Gaurav, Hayase, Shuzi, and Pandey, Shyam S.

Subjects

*DYE-sensitized solar cells, *ZINC porphyrins, *COBALT, *PORPHYRINS, *PHOTOSENSITIZERS, *ELECTROLYTES, *ELECTROCHEMICAL analysis

Abstract

• Flexible SUS-mesh with optimally protected Ti metal was proved to be an efficient photoanode. • The interfacial contact between the nanoporous TiO 2 and flexible photoanode was found to influence the device performance. • TiO 2 with relatively larger particle size provided facile charge transport. Transparent-conductive-oxide-free (T-C-O-free) back-contact (B-C) dye-sensitized solar cell (DSC) utilizing flexible Stainless Steel (SS) mesh (SS-mesh) supported with mesoporous TiO 2 as a photoanode employing cobalt electrolyte is being presented. A thin layer of Ti metal over the SS-mesh was ascertained to be essential to retard the back electron reaction, which was confirmed by the dark current measurements. The interfacial contact between the SS-mesh and nanoporous (NP) TiO 2 of the photoanode of T-C-O-free B-C-DSC was driven to influence the photovoltaic performance greatly. It was confirmed by electrochemical impedance analysis that NP TiO 2 of 30 nm exhibited less charge transfer impedance observed at TiO 2 -dye-electrolyte interface as compared to TiO 2 of having particle size of 15–20 nm. T-C-O-free B-C-DSC employing dye mixer combination of indoline dyes D-131 and D-205 (1:1) with relatively larger NP of TiO 2 (30 nm) as compared to TiO 2 of 15–20 nm exhibited enhanced photoconversion efficiency (PCE) of 4.02%. To increase the PCE even further, T-C-O-free B-C-DSC with cobalt based electrolyte sensitized with porphyrin (YD2-o-C8)-dye bearing a larger optical window was investigated. An optimized 10 µm thickness of the TiO 2 layer was found to be optimum leading to an enhanced PCE of 5.26%. [ABSTRACT FROM AUTHOR]

Published

2020

11. Performance optimization of back-contact perovskite solar cells with quasi-interdigitated electrodes.

Author

Shalenov, Erik O., Dzhumagulova, Karlygash N., Ng, Annie, and Jumabekov, Askhat N.

Subjects

*SOLAR cells, *ELECTRODES, *OPTICAL losses, *SILICON solar cells, *LIGHT transmission, *PHOTOVOLTAIC cells, *COMPUTER simulation

Abstract

• Computer simulation method is used to study back-contact perovskite solar (BC-PSCs). • Geometric parameters of quasi-interdigitated electrodes (QIDEs) are optimized. • Optimum electronic properties for the perovskite layer are obtained. • BC-PSC with QIDEs have low optical transmission losses. A numerical simulation method is used to investigate intricacies of a complex relation between the back-contact electrode (BCE) geometric parameters, the perovskite photo-absorber layer electronic properties, and device performance in back-contact perovskite solar cells (BC-PSCs) with quasi-interdigitated electrodes (QIDEs). To unlock the full potential of BC-PSC with QIDEs, the device performance was investigated by systematically varying the geometric parameters of BCE and the perovskite photo-absorber layer electronic parameters in order to determine the conditions for a best device performance. BC-PSC with QIDEs have a potential to produce power conversion efficiencies (PCEs) higher than PSCs with the conventional sandwich architecture if optimized parameters for electrode geometry and perovskite electronic properties are used. The findings of the present work give an insight into the work principle of these devices and provide a theoretical guidance for design and fabrication of high-performance BC-PSC with QIDEs. [ABSTRACT FROM AUTHOR]

Published

2020

12. Optical design and optimization for back-contact perovskite solar cells.

Author

Yang, Weichuang, Yang, Zhenhai, Shou, Chunhui, Sheng, Jiang, Yan, Baojie, and Ye, Jichun

Subjects

*SOLAR cells, *SILICON solar cells, *CHARGE carrier lifetime, *QUANTUM efficiency, *LIGHT absorption

Abstract

• J ph of 24.03 mA/cm2 is received under 300 nm-thick and 1.55 eV band gap. • Excellent optical performance is mainly attributed to the light trapping effect. • High J ph maintains under varied perovskite thickness, band gap and incident angles. • The internal quantum efficiency (IQE) is study by a brief electrical simulation. Interdigitated back-contact (IBC) structure has been successful explored for optimal light-harvesting in the silicon solar cells (SCs), but less used in perovskite solar cells (PSCs). To unlock the full potential of IBC PSCs, we investigate numerically the photo-electrical performance of this type of IBC PSCs, designing the light-trapping structures and screening the functional materials. Taking the experimental quasi-interdigitated back-contact (QIBC) structure as the original model, the optical absorption of PSCs can be boosted by befitting anti-reflective coating thickness and rear substrate materials. And then the QIBC PSC yields the maximal photocurrent density of 24.03 mA/cm2, 4.19 mA/cm2 higher than that of the conventional sandwich PSC. The light-trapping effect of QIBC architecture is discussed by addressing the absorption spectra and the cross-sectional electric field distributions of perovskite layer. Besides, better optical properties can be well maintained in a large range of film thickness and band gap of perovskite, as well as incident angles, compared with that of sandwich PSC. More importantly, an approximate electrical simulation is implemented, revealing the relationship between the internal quantum efficiency, the carrier diffusion length of perovskite and the electrode finger distance. Therefore, the simulation results are expected to provide the theoretical guidance for developing high efficiency IBC PSCs. [ABSTRACT FROM AUTHOR]

Published

2020

13. Engineering of effective back-contact barrier of CZTSe: Nanoscale Ge solar cells – MoSe2 defects implication.

Author

Lee, Sanghyun, Price, Kent J., Saucedo, Edgardo, and Giraldo, Sergio

Subjects

*SOLAR cells, *DC sputtering, *MAGNETRON sputtering, *NANOELECTROMECHANICAL systems

Abstract

• The effective back-contact barrier of CZTSe: nanoscale Ge is improved and characterized. • The mechanism of the back-contact improvement is demonstrated with device models. • The model of MoSe 2 interface defect at back-contact agrees with the empirical data. • The efficiency is improved up to 8.3% by including nanolayer Ge at back contact. Using temperature-dependent measurements and device modeling, we systematically study the effective back-contact barrier of CZTSe devices to improve the property of the back-contact interface. By comparing with CZTSe devices with various nanoscale Ge configurations, CZTSe nanoscale Ge bi-layers devices show the improved power conversion efficiency by 1.1%. DC magnetron sputtering is used to fabricate CZTSe: nanolayer Ge devices. Critical device parameters are characterized to understand the impact of nanoscale Ge films on the back-contact device characteristics. Based on empirical results, modeling is performed for the influence of MoSe 2 defects on the effective back-contact barrier. Analysis of experimental results of Ge bi-layers devices with the improved back-contact barrier makes a good agreement with modeling and Sentaurus TCAD simulation at the 95% confidence-level. The conversion efficiency of CZTSe: nanoscale Ge bi-layers devices is improved up to 8.3%. [ABSTRACT FROM AUTHOR]

Published

2019

14. Novel carbon‐based material for perovskite solar cells back‐contact.

Author

Teixeira, Cristina O., Andrade, Luísa, and Mendes, Adélio

Subjects

*SOLAR cells, *CARBON paper, *CARBON-black, *SILICON solar cells, *MATERIALS, *PEROVSKITE

Abstract

Summary: Perovskite solar cells are one of the most promising photovoltaic technology, presenting the fastest power conversion efficiency (PCE) growth from 3.8 % to 24.2 % in just 10 years. However, there are still challenges hindering its commercialization such as the expensive back‐contact made of gold. Carbon‐based materials, mainly carbon pastes made of carbon black and graphite, have already proven to be good candidates as back‐contacts because of their features such as low cost, high conductivity, and high stability. In this work, the replacement of gold back‐contact by a carbon paper with a microporous layer coated with a PEDOT:PSS dispersion is reported. To the best of the author's knowledge, this material has never been reported for perovskite solar cells. A PCE of 9.22 % was obtained, representing 62 % of the PCE obtained for the same cell but with a gold back‐contact. [ABSTRACT FROM AUTHOR]

Published

2019

15. Technology Support for High-Throughput Processing of Thin-Film CdTe PV Modules: Final Technical Report, April 1998 - October 2001

Author

Powell, R

Published

2002

16. Polyimide for silicon solar cells with double-sided textured pyramids.

Author

Zin, Ngwe, Mcintosh, Keith, Bakhshi, Sara, Vázquez-Guardado, Abraham, Kho, Teng, Fong, Kean, Stocks, Matthew, Franklin, Evan, and Blakers, Andrew

Subjects

*POLYIMIDE films, *SILICON solar cells, *RECOMBINATION in semiconductors, *INTEGRATED circuit passivation, *SILICON nitride

Abstract

Silicon solar cells incorporating double-sided pyramidal texture are capable of superior light trapping over cells with front-side only texture. However, increased surface area, roughness and exposed <111> crystal planes of textured surfaces not only causes increased recombination, but also makes cells susceptible to shunting through pinholes in the dielectric at the sharp peaks and valleys of the textured pyramids. A polyimide film as an insulating interlayer film is investigated to circumvent the tradeoff between improved light trapping, increased recombination and increased shunt paths. When applied at the rear of the interdigitated back contact silicon solar cell structure, the polyimide film provides an excellent electrical insulation (> 1000 MΩ of insulation resistance) and increases photocurrent (~ 1.1 mA/cm 2 ) owing to an increased rear internal reflectance. The polyimide is also compatible with metal annealing of passivating dielectrics such as silicon nitride. Optical simulation and experimental results are combined in a 3D semiconductor simulation (Quokka) to quantify the possible gain of implementing the double-sided texture in high efficiency silicon solar cells. [ABSTRACT FROM AUTHOR]

Published

2018

17. Back-contact perovskite solar cells with honeycomb-like charge collecting electrodes.

Author

Hou, Qicheng, Bacal, Dorota, Jumabekov, Askhat N., Li, Wei, Wang, Ziyu, Lin, Xiongfeng, Ng, Soon Hock, Tan, Boer, Bao, Qiaoliang, Chesman, Anthony S.R., Cheng, Yi-Bing, and Bach, Udo

Abstract

Back-contact electrodes have been broadly applied to silicon photovoltaics to enhance their performance and avoid parasitic absorption from window materials and charge collection grids [1,2]. Here we introduce an innovative back-contact design for perovskite solar cells (PSCs) derived from our recently described quasi-interdigitated back-contact architecture [3]. The back contact consists of a top electrode, which has a honeycomb-like grid geometry, that is separated from the underlying planar bottom electrode by a similarly shaped insulating Al 2 O 3 layer. This new design has higher structural robustness, as well as better defect tolerance, resulting in the highest short-circuit current (~ 16.4 mA/cm 2 ) and stabilized power output (~ 4%) for a back-contact PSC to date. The improved performance was attributed to an increased charge collecting efficiency, with photocurrent mapping revealing what electrode dimensions are required for optimum efficiency. [ABSTRACT FROM AUTHOR]

Published

2018

18. Mechanical and electrical properties of wave-shaped wires for low-stress interconnection of solar cells.

Author

Rendler, L.C., Walter, J., Goldenberg, S., Beinert, A.J., Wiese, S., and Eitner, U.

Subjects

*SOLAR cells, *METALLIC wire, *INTEGRATED circuit interconnections, *MECHANICAL properties of metals, *ELECTRIC properties of metals, *THERMOMECHANICAL treatment, *METALS

Abstract

In the manufacturing process of a common solar module, crystalline silicon solar cells are interconnected by soldering. Copper-based interconnectors, coated with a solder alloy are soldered on both sides of the solar cells on the contact metallization. Subsequently, the solar cell strings are embedded in between two sheets of encapsulant, commonly ethylene-vinyl acetat (EVA), which itself attaches to a front glass and a back sheet during the lamination process. Thermomechanical stress, due to the mismatch of the coefficients of thermal expansion (CTE) of copper and silicon, causes bowing of a back-contact solar cell after the soldering process. Additionally, thermomechanical stress can result in the failure of solder joints. By adapting the mechanical properties of an interconnector, thermomechanical stress can be reduced. Shaping a straight wire with a round cross section to a wave-like form reduces its effective tensile mechanical properties and leads to changes of its effective electrical conductivity. This study investigates the mechanical and electrical properties of wave-shaped wires with different amplitudes, periods and diameters. In addition, microscopic imaging reveals the geometry and potential defects due to the shaping process. The influence of the shaping process on the yield limit of commercially available copper-based wires is determined. For this reason, an algorithm is designed that allows the automatic and precise determination of the yield limit of these interconnectors. In this study, a maximum yield limit reduction of 88.5% compared to a straight wire is found. Furthermore, the influence of the shaping process on the electrical resistance is analyzed. For this purpose, the influence of wire damaging due to the shaping process, as well as the wires longitudinal length change is determined. An increase of the electrical resistance between 3.5% and 82.7% is measured. To choose an optimal interconnection concept for solar cells, the mechanical, as well as the electrical properties of the interconnectors have to be considered. This study correlates the advantageous longitudinal softness of wave-shaped wires, which potentially leads to a significant decrease of the thermomechanical stress in solar cells and of the bowing of back-contact solar cells, with the disadvantageous increase of the electrical resistance caused by the shaping process. The findings enable an optimization of a wire-based interconnection concept for back-contact solar cells. [ABSTRACT FROM AUTHOR]

Published

2018

19. Low temperature deposition of bifacial CIGS solar cells on Al-doped Zinc Oxide back contacts.

Author

Cavallari, Nicholas, Pattini, Francesco, Rampino, Stefano, Annoni, Filippo, Barozzi, Mario, Bronzoni, Matteo, Gilioli, Edmondo, Gombia, Enos, Maragliano, Carlo, Mazzer, Massimo, Pepponi, Giancarlo, Spaggiari, Giulia, and Fornari, Roberto

Subjects

*SOLAR cell design, *ALUMINUM compounds, *DOPING agents (Chemistry), *ZINC oxide, *GALLIUM compounds

Abstract

We report on the fabrication and characterization of Cu(In,Ga)Se 2 (CIGS)-based thin film bifacial solar cells using Al-doped ZnO (AZO) as cost-effective and non-toxic transparent back contact. We show that, by depositing both CIGS and AZO by Low Temperature Pulsed Electron Deposition at a maximum temperature of 250 °C, a good ohmic contact is formed between the two layers and good quality solar cells can be fabricated as a result. Photovoltaic efficiencies as high as 9.3% (front illumination), 5.1% (backside illumination) and 11.6% (bifacial illumination) have been obtained so far. These values are remarkably higher than those previously reported in the literature. We demonstrate that this improvement is ascribed to the low-temperature deposition process that avoids the formation of Ga 2 O 3 at the CIGS/AZO interface and favours the formation of a low-resistivity contact in agreement with device simulations. [ABSTRACT FROM AUTHOR]

Published

2017

20. Slot-Die-Coated Active Layer for Printed Flexible Back-Contact Perovskite Solar Cells

Author

Mayuribala Mangrulkar, Hryhorii Parkhomenko, and Askhat Jumabekov

Subjects

QIBC, slot-die coating, Materials Chemistry, flexible substrates, Surfaces and Interfaces, back-contact, perovskite solar cell, Surfaces, Coatings and Films

Abstract

Perovskites have already shown potential as active layers in photovoltaic applications. Furthermore, a low-cost and simple solution processing technology allows perovskites to be used in flexible and printed electronics. Perovskite solar cells (PSC) with a back-contact (BC) structure, in which the electrode system is based on a quasi-interdigitated back-contact (QIBC) design, promise to increase the power conversion efficiency (PCE) of devices beyond those that can be obtained using PSCs with a traditional sandwich structure. While the spin-coating technique is used to deposit the perovskite layer of lab-scale BC PSCs, the application of large-area printing techniques to deposit the perovskite layer of such devices is yet to be explored. Therefore, this work demonstrates an application of the slot-die coating technique to print the perovskite active layer of BC PSCs with QIBC electrodes on flexible polymer substrates. The morphology of the obtained perovskite films on QIBC electrodes are investigated and the primary photoelectric parameters of the resulting BC PSCs are measured. The charge carrier recombination processes in the fabricated BC PSCs are investigated and the dominant mechanism for carrier loss in the devices is determined. The findings of the work give an insight into the properties of the slot-die-coated perovskite active layer of BC PSCs and points to exciting new research opportunities in this direction.

Published

2023

21. Front-floating Emitter Voltage Mapping of IBC Mercury Cells.

Author

Spinelli, Pierpaolo, Guillevin, Nicolas, Burgers, Teun, Mewe, Agnes, Vlooswijk, Ard, Geerligs, Bart, Weeber, Arthur, and Cesar, Ilkay

Abstract

Standard characterization techniques such as LBIC are difficult to apply to IBC solar cells with a front floating emitter (FFE). This is because the cells need to be under bias illumination, and this is often impossible in commercial LBIC measurement tools. To the best of our knowledge, LBIC measurements on FFE IBC cells have not been published so far. In this work we present a experimental method to spatially characterize the FFE of IBC cells and gain insights on electrical shading losses, without using LBIC. This method makes use of the commercially available CoreScan device, mapping the FFE voltage relative to the shorted back-contacts over the cell area. Using this technique we were able to resolve busbar, pads and finger features of both polarities with a scan of the front side. The scan shows that BSF features have higher voltage than emitter features, thus giving a direct evidence of the FFE pumping effect. If coupled to circuit simulation, FFE voltage maps can be the base for estimating electrical shading losses in IBC cells. The FFE voltage maps also give information on the homogeneity of the pumping effect across the wafer, e.g. affected by diffusion non-uniformity, and at least qualitatively its effect on the cell performance. [ABSTRACT FROM AUTHOR]

Published

2015

22. Cross Testing Electrically Conductive Adhesives and Conductive Back-sheets for the ECN Back-contact Cell and Module Technology.

Author

Broek, K.M., Bennett, I.J., Kloos, M.J.H., and Eerenstein, W.

Abstract

ECN set up a cross testing project in which suppliers of electrically conductive adhesives (ECA) and conductive back-sheet (CBS) foils participated. In the component part of the project, combinations of adhesive and foil were characterised for peel strength and contact resistance. The separate components were tested on dot geometry (ECA) and surface structure (CBS). In the module manufacture and testing part, 12 combinations of ECA and CBS were used in 4-cell MWT modules. The modules were tested up to 2000 hours in damp heat and 400 thermal cycles (both tests, 2 times the requirement of IEC61215). Most combinations passed the 5% power loss criterion. One of the conductive adhesives performed well on three different types of back-sheet which is supportive of a robust technology. Other results show that it is important to thoroughly test interesting combinations of ECA and CBS at module level before adding them to the recommended bill of materials. [ABSTRACT FROM AUTHOR]

Published

2015

23. Simplified Front Surface Field Formation for Back Contacted Silicon Solar Cells.

Author

Kimmerle, Achim, Woehl, Robert, Wolf, Andreas, and Biro, Daniel

Abstract

Abstract: We investigate the formation of deep Phosphorus diffusion profiles with low surface concentrations in one single diffusion step. Such processes are suited for front surface field formation for n-type back-contact back-junction (BC- BJ) silicon solar cells or p-type silicon solar cells with alternative metallization techniques. The deposition temperature allows accurate control of the sheet resistance whereas the temperature of the in-situ oxidation strongly influences the profile-depth and surface concentration. The newly developed process leads to low dark saturation current densities well below 30 fA/cm2 on alkaline-textured surfaces and low short circuit current loss at the front side. Due to their depth and adjustable surface concentration, the obtained profiles are promising for front-surface- fields (FSF) and novel n-type emitters. A first implementation in BC-BJ solar cells with aluminum-alloyed emitter shows a good blue response of the solar cells and an improved efficiency compared to the reference process by 0.6%abs. [Copyright &y& Elsevier]

Published

2013

24. Continued Development of All-Back-Contact Silicon Wafer Solar Cells at ANU.

Author

Zin, Ngwe, Blakers, Andrew, McIntosh, Keith R., Franklin, Evan, Kho, Teng, Chern, Kean, Wong, Johnson, Mueller, Thomas, Aberle, Armin G., Yang, Yang, Zhang, Xueling, Feng, Zhiqiang, Huang, Qiang, and Verlinden, Pierre J.

Abstract

Abstract: The collaboration between the Solar Energy Research Institute of Singapore (SERIS), Trina Solar and ANU is progressing well, and ANU has already developed all-back-contacted (ABC) silicon wafer cells with best one-sun efficiencies of 21.2% and 22.1% on FZ material, when measured with the aperture areas of 16cm2 (includes busbars) and 13cm2 (excludes busbars) respectively. This paper presents the continuing development of ABC cells targeting the efficiency of 23.5% on 16-cm2 cell area. Further developments such as optimising front surface field (FSF), rear diffusion, anti-reflection coating (ARC), and incorporation of lithographically aligned metal contacts were undertaken on the ABC cells. Phosphorus diffusion of the FSF was made lighter from the sheet resistance of 190Ω/□ to 240Ω/□, resulting in the reduction of the saturation current density (Joe) of the FSF by 22 fA/cm2. The optimised thickness of anti-reflection coating (ARC) PECVD SiNx further reduces the average reflectance across the wavelength range of 300 to 1200nm by about 4%. Incorporation of aligned metal contacts and heavier rear phosphorus diffusion has contributed to the reduction in the total series resistance by 0.08Ωcm2. The above optimised improvements have increased the efficiency of the champion ABC cell by 0.5% absolute. In addition, we present further refinements in areas of texturing; FSF passivation; electrical shading loss in terms of cell pitch, bus- bar and base doping; and metallisation to aim for the 16-cm2 ABC cells with the conversion efficiency > 22% in the near term. [Copyright &y& Elsevier]

Published

2013

25. High Efficiency Silicon Solar Cells.

Author

Blakers, Andrew, Zin, Ngwe, McIntosh, Keith R., and Fong, Kean

Abstract

Abstract: Silicon remains the material of choice for photovoltaics because of its abundance, non-toxicity, high and stable cell efficiencies, the maturity of production infrastructure and the deep and widespread level of skill available in relation to silicon devices. Rapidly decreasing module prices mean that area-related balance of systems costs are an increasing proportion of photovoltaic systems price. This places a premium on efficient cells. In recent years there have been large improvements in mass production of high quality wafers, the ability to handle thin wafers, maintenance of high minority carrier lifetimes, surface passivation, minimisation of optical losses, device characterisation and in other areas. Many of these improvements are viable in mass production. The upper limit of silicon solar cell efficiency is 29%, which is substantially higher than the best laboratory (25%) [1] and large-area commercial (24%) [2,3] cells. Cell efficiencies above 25% appear to be feasible in both a laboratory and commercial environment. Such a cell will have minimal bulk recombination due to a combination of a thin substrate with a very high minority carrier lifetime; superb surface passivation; small-area electrical contacts consistent with low contact recombination, free carrier absorption and contact resistance; excellent optical control through the use of texturing, antireflection coatings and rear surface reflectors; low edge recombination assisted by the use of thinner wafers, larger cells and edge passivation; and sufficient metal coverage to minimise resistive losses. This paper will survey current work in high- performance silicon solar cell design and fabrication, and discuss approaches to efficiency improvements. [Copyright &y& Elsevier]

Published

2013

26. Highly efficient all-screen-printed back-contact back-junction silicon solar cells with aluminum-alloyed emitter.

Author

Woehl, R., Krause, J., Granek, F., and Biro, D.

Subjects

SEMICONDUCTOR junctions, SOLAR cells, ALUMINUM alloying, SCREEN process printing, MICROFABRICATION, OXIDATION, SURFACES (Technology), SILICON

Abstract

Abstract: All-screen-printed back-contact back-junction silicon solar cells with aluminum-alloyed emitter on n-type base material were fabricated and analyzed at Fraunhofer ISE PV-TEC. Three different process sequences are compared to each other. One process flow with shallow phosphorus profiles realizes cells with efficiencies of 19.7%. Using a long thermal oxidation, cells with deep driven-in phosphorus profiles (front and back surface field) were processed where solar cell efficiencies of 20.0% are realized. Both cell efficiencies are independently measured at Fraunhofer ISE CalLab on a designated area of 16.65cm2. The specific contact resistivity of screen-printed and fired silver paste to silicon surfaces with different phosphorus profiles was determined in dependence of several firing conditions. The main developed features of the presented cell structure comprise the firing-stable front and rear passivation layers, the spiking-free passivation layer against aluminum and the deep driven-in phosphorus profile that can be contacted by silver screen-printing paste in a firing step. [Copyright &y& Elsevier]

Published

2011

27. Back-contact back-junction silicon solar cells under UV illumination

Author

Granek, F. and Reichel, C.

Subjects

*SOLAR cells, *SEMICONDUCTOR junctions, *ULTRAVIOLET radiation, *PERFORMANCE evaluation, *PHOTONS, *SURFACE analysis, *DIFFUSION, *SEMICONDUCTOR doping

Abstract

Abstract: The performance of n-type Si back-contact back-junction (BC-BJ) solar cells under illumination with high energy ultraviolet (UV) photons was investigated. The impact of the phosphorus doped front surface field (FSF) layer on the stability of the front surface passivation under UV illumination was investigated. Lifetime samples and solar cells without the front surface field showed a significant performance reduction when exposed to ultraviolet light. The surface saturation current density (J 0e) increased from 48 to 446fA/cm2 after the UV exposure. At the same time the efficiency of the BC-BJ solar cells without the FSF diffusion reduced from 19.8% to 14.3%. In contrast to the lifetime samples and solar cells without the FSF diffusion, the tested n+nn+ structures and the BC-BJ solar cells with applied FSF diffusion profiles were significantly more stable under UV exposure, i.e. J 0e increased only by a factor of 25% and the efficiency of these cells decreased only 0.3%abs by the UV illumination. Finally it was shown that the performance of the UV-degraded solar cells without FSF could be improved during a forming gas anneal (FGA). Due to application of FGA the efficiency almost fully recovered from 14.3% to 19.6%. [Copyright &y& Elsevier]

Published

2010

28. Modeling and optimization study of industrial n-type high-efficiency back-contact back-junction silicon solar cells

Author

Kluska, Sven, Granek, Filip, Rüdiger, Marc, Hermle, Martin, and Glunz, Stefan W.

Subjects

*SILICON solar cells, *SEMICONDUCTOR junctions, *SUBSTRATES (Materials science), *RECOMBINATION in semiconductors, *ELECTRIC resistance, *ELECTRIC loss in electric power systems

Abstract

Abstract: The knowledge of the loss mechanisms in industrial back-contact back-junction (BC BJ) silicon solar cells and their dependence on geometrical and substrate parameters provides the opportunity to further increase the cell efficiency of this cell type. In the presented paper the influences of the different loss mechanisms on the cell parameters of BC BJ solar cells were analyzed. The basis of the simulations was an advanced 1-d model that regards the detrimental influences of intrinsic losses, optical losses, series resistance losses and recombination losses on the cell efficiency. In this context the main influence of electrical shading losses will be discussed in particular, due to the restrictions of the minimum base width as a result of industrial structuring processes. The predictions of the theoretical calculations will be compared with the measured cell parameters of BC BJ solar cells for various cell designs. In order to further improve the cell design the influences of geometrical parameters (pitch, base width) and substrate parameters (base resistivity) on the cell efficiency will be analyzed. The modeling data show that the optimum cell geometry defines a balance between series resistance and electrical shading losses. [Copyright &y& Elsevier]

Published

2010

29. Phase control of Cu x Te film and its effects on CdS/CdTe solar cell

Author

Wu, X., Zhou, J., Duda, A., Yan, Y., Teeter, G., Asher, S., Metzger, W.K., Demtsu, S., Wei, Su-Huai., and Noufi, R.

Subjects

*PROPERTIES of matter, *SEMICONDUCTOR doping, *SOLUTION (Chemistry), *OXIDES

Abstract

Abstract: Phase control is critical for achieving high-performance CdTe cells when Cu x Te is used as a back-contact for CdTe cells. Cu x Te phases are mainly controlled by the Cu/Te ratio, and they can also be affected by post-heat-treatment temperature. Although Cu2Te has the highest conductivity, it is unstable and provides more Cu diffusion into the CdS and CdTe films. Cu diffusion into the CdS causes “cross-over”, and Cu diffusion into the CdTe film creates Cu-related defects that lower photogenerated carrier lifetime and result in voltage-dependent collection. A “recontact” experiment clearly indicated that the mechanism giving rise to “roll-over” is the formation of Cu-related oxides, rather than the loss of Cu on the back-contact. [Copyright &y& Elsevier]

Published

2007

30. Effect of ZnTe/ZnTe:Cu complex back-contact on device characteristics of CdTe solar cells.

Author

Wu, LiLi, Feng, LiangHuan, Li, Wei, Zhang, JingQuan, Li, Bing, Lei, Zhi, Cai, Wei, Cai, YaPing, and Zheng, JiaGui

Abstract

ZnTe/ZnTe:Cu complex layers deposited by vacuum co-evaporation have been introduced to CdS/CdTe solar cells. The C-V and I-V curves have been investigated and the effects of un-doped ZnTe layer thickness as well as annealing temperatures on I-V characteristics of CdTe solar cells have been studied. The results show that the “roll over” and “cross over” phenomena of dark and light I-V curves can be eliminated by use of ZnTe/ZnTe:Cu layer and the fill factor for a typical sample has increased to 73%, where there is no high resistance transparent layer. The reasons have been discussed combined with the energy band diagram of CdTe solar cells. [ABSTRACT FROM AUTHOR]

Published

2007

31. Interconnection 1, 2, 3, 4.0: Buildup towards a PV Technology Hero?

Author

Borgers, Tom, Govaerts, Jonathan, Van Dyck, Rik, El-Chami, Ibrahim, Nivelle, Philippe, van der Heide, Arvid, Voroshazi, Eszter, Manganiello, Patrizio, Szlufcik, Jozef, Poortmans, Jef, Bervoets, Robin, Vastmans, Luc, Moors, Reinoud, and Doumen, Geert

Subjects

photovoltaic, fabric, New Materials and Concepts for Cells and Modules, multi-wire, New Materials and Concepts for Photovoltaic Devices, bifacial, back-contact, interconnection, solar

Abstract

36th European Photovoltaic Solar Energy Conference and Exhibition; 1-5, In this paper an overview of interconnection technologies for bifacial and back-contacted (bifacial) cells in different stages of their development is reported, leading to a new technology suited for efficient interconnection of (bifacial) back-contact cells.

Published

2019

32. Performance evaluation of different designs of back-contact perovskite solar cells.

Author

Shalenov, Erik O., Seitkozhanov, Yeldos S., Valagiannopoulos, Constantinos, Ng, Annie, Dzhumagulova, Karlygash N., and Jumabekov, Askhat N.

Subjects

*SOLAR cells, *PHOTOVOLTAIC power systems, *PEROVSKITE, *ARCHITECTURAL design, *ELECTRODES

Abstract

Back-contact design for the architecture of devices is a promising approach to develop high-performance perovskite solar cells. Here, numerical simulation methods are used to investigate device properties of back-contact perovskite solar cells (BC–PSCs) with the quasi-interdigitated, flat-interdigitated, and interdigitated electrode designs. The results highlight the principal differences in the designs of the electrodes and provide an investigation and analysis of the impact of these electrodes on the photovoltaic properties of their BC-PSCs. The effect of the perovskite photoactive layer electronic properties on the performance of BC-PSCs is also investigated. It is revealed that while BC-PSCs with the quasi-interdigitated electrode design can potentially produce power conversion efficiencies (PCEs) well above 25 %, BC-PSCs with the flat-interdigitated and interdigitated electrode designs are more tolerant to electronic imperfections in the perovskite layer and can produce PCEs higher than those in devices with the quasi-interdigitated electrode design. Manufacturing and prospective use of electrodes with the quasi-interdigitated, flat-interdigitated, and interdigitated designs in developing BC-PSCs are discussed from the experimental standpoint. • Numerical simulations are employed to investigate device properties of back-contact perovskite solar cells with various device designs. • Back-contact perovskite solar cells with quasi-interdigitated electrodes could give >25 % efficiency under optimal conditions. • Devices with flat quasi-interdigitated and interdigitated electrodes are more tolerant to imperfections in the perovskite layer. • The findings of this work can be used for designing back-contact perovskite solar devices with the best performance. [ABSTRACT FROM AUTHOR]

Published

2022

33. Laminated photovoltaic modules using back-contact solar cells

Author

Worobey, Walter [Albuquerque, NM]

Published

1999

34. Method of monolithic module assembly

Author

Worobey, Walter [Albuquerque, NM]

Published

1999

35. Lithography-free and dopant-free back-contact silicon heterojunction solar cells with solution-processed TiO2 as the efficient electron selective layer

Author

Gangqiang Dong, Yuqin Zhou, Qunfang Zhang, Fengchao Li, Donghong Yu, Yurong Zhou, Zhenghao Liu, Zhenjun Fan, Fengzhen Liu, Zhengxiong Cai, Zongheng Sun, and Qi Wang

Subjects

Materials science, Passivation, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, Dopant-free, law, Plasma-enhanced chemical vapor deposition, Solar cell, Lithography-free, Dopant, Renewable Energy, Sustainability and the Environment, business.industry, Heterojunction, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Amorphous solid, Back-contact, Optoelectronics, Photolithography, 0210 nano-technology, business, Layer (electronics)

Abstract

Lithography-free interdigitated back-contact silicon heterojunction (IBC-SHJ) solar cells with dopant-free metal oxides (TiO2 and MoOx) as the carriers selective transport layers were investigated. Spin-coating and hot-wire reactive-sublimation deposition together with low cost mask technology were used to fabricate the solar cells. Insertion of a SiOx layer with the thickness of about 2.4 nm between the intrinsic amorphous Si (a-Si:H(i)) passivation layer and the spin-coated TiO2 layer greatly improves the solar cell performance due to the enhanced field-effect passivation of the a-Si:H(i)/SiOx/TiO2 layer stack. Efficiency up to 20.24% was achieved on the lithography-free and dopant-free IBC-SHJ devices with a-Si:H(i)/SiOx/TiO2 layer stack as the electron selective transport layer, a-Si:H(i)/MoOx as the hole selective transport layer, and WOx as the antireflection layer. The novel IBC-SHJ solar cells show significant advantages in simplification of the technology and process compared with the IBC-SHJ devices whose back surface pattering and carrier selective layers relied on photolithography and plasma enhanced chemical vapor deposition (PECVD).

Published

2019

36. Easy processing carbon paper electrode for highly efficient perovskite solar cells.

Author

Teixeira, Cristina O., Andrade, Luísa, and Mendes, Adélio

Subjects

*CARBON paper, *SOLAR cells, *CARBON electrodes, *CORPORATE bonds, *OHMIC contacts, *SILICON solar cells, *DYE-sensitized solar cells, *SOLAR technology

Abstract

Perovskite solar cells are by far the photovoltaic technology with the fastest efficiency evolution, reaching now the astonishing power conversion efficiency (PCE) of 25.2%. Their advantages cover also color and transparency, extremely low thickness, low cost, simple fabrication methods and versatile designs. Nevertheless, since it is a young technology, there are still several challenges that need to be overcome for making its commercialization feasible. For making perovskite solar modules, the back-contact plays a critical job since it drives and deliveries the low energy electrons to the p contact of the cell. In n-i-p configuration cells, gold is normally used as back-contact, which is expensive and rare. In this work, several commercial carbon papers and application procedures were investigated. The best performing system produced 89% of the PCE obtained with standard gold back-contact. Besides having a much simpler and cheaper application method, other features such as low cost, great chemical and mechanical stability and low electrical resistivity proved carbon papers potential for commercialization. Moreover, when a gold interlayer of 5 nm was applied, the relative PCE increased up to 92%. Image 1 • A PCE record value is reported for a PSC with a carbon paper back-contact. • The application method of the novel carbon back-contact is extremely simple. • The carbon paper features low sheet resistance (0.5 Ω/sq) and near ohmic contact. • A gold thin layer was used to enhance charge extraction at the back-contact. [ABSTRACT FROM AUTHOR]

Published

2020

37. Carbon-nanofibers film as a back-contact buffer layer in CdTe thin film solar cell.

Author

Masood, Hafiz Tariq, Anwer, Shoaib, Wang, Xin, Ali, Abbas, and Deliang, Wang

Subjects

*BUFFER layers, *SOLAR cells, *THIN films, *SILICON solar cells, *VALENCE bands, *X-ray photoelectron spectroscopy

Abstract

Carbon nanofibers (CNFs) based thin films were introduced as a buffer layer in the back contact of of CdTe thin film solar cells. CNFs buffer layer is used to replace the conventional metal contact layer. Quantitative band alignment measurement by using X-ray photoelectron spectroscopy (XPS) demonstrated that a relatively low energy barrier at the CNF/CdTe interface was formed. The valance band offset of 0.47 eV and conduction band offset of 0.80 eV were examined between CNF and CdTe.. The stability of CdTe solar cells was considerably improved by introducing CNF buffer layer with trace amount of Cu to fabricate low-energy barrier back contact. The CNFs as a buffer layer between CdTe and metal Au electrode based fabricated CdTe thin film solar cells demonstrated a conversion efficiency of 11.4 %. From the device stability stressing tests we conclude that CNFs as a buffer layer in a CdTe thin film solar cell meaningfully improved the cell performance and device stability. [ABSTRACT FROM AUTHOR]

Published

2020

38. Optimized analysis of back-contact perovskite solar cells architectures.

Author

Fang, Guochuan, Tian, Hanmin, Chang, Weihong, Wang, Zheng, He, Quanmin, and Gao, Xinyue

Subjects

*SOLAR cells, *SILICON solar cells, *CHARGE carrier lifetime, *PEROVSKITE analysis, *CELL anatomy

Abstract

The perovskite solar cells with back-contact structure was reported recently that its carriers have a good diffusion length of 12 μm, which was considered as an innovational way to improve the cell's power conversion efficiency (PCE). Based on this reported experiment, the diffusion and drift of photogenerated carriers of the back-contact structure perovskite solar cell are calculated here detailly. Furthermore, the influence of carrier diffusion length, geometric scale, position of back-contact buried gate, and structure of the cell on performance is analyzed. The results showed that the PCE of a modified back-contact perovskite solar cell is superior to that of reported back-contact structure cell and traditional p-i-n structure cell under the same material parameters. It shows that the modified back-contact perovskite solar cell with optimized parameters achieved PCE of 28.27 %. [ABSTRACT FROM AUTHOR]

Published

2020

39. High Efficiency Silicon Solar Cells

Author

Ngwe Zin, Andrew Blakers, Keith R. McIntosh, and Kean Fong

Subjects

Materials science, Passivation, Silicon, business.industry, Photovoltaic system, Contact resistance, chemistry.chemical_element, Nanotechnology, Carrier lifetime, chemistry, Energy(all), High-efficiency, Photovoltaics, Back-contact, Optoelectronics, Wafer, Free carrier absorption, business

Abstract

Silicon remains the material of choice for photovoltaics because of its abundance, non-toxicity, high and stable cell efficiencies, the maturity of production infrastructure and the deep and widespread level of skill available in relation to silicon devices. Rapidly decreasing module prices mean that area-related balance of systems costs are an increasing proportion of photovoltaic systems price. This places a premium on efficient cells. In recent years there have been large improvements in mass production of high quality wafers, the ability to handle thin wafers, maintenance of high minority carrier lifetimes, surface passivation, minimisation of optical losses, device characterisation and in other areas. Many of these improvements are viable in mass production. The upper limit of silicon solar cell efficiency is 29%, which is substantially higher than the best laboratory (25%) [1] and large-area commercial (24%) [2] , [3] cells. Cell efficiencies above 25% appear to be feasible in both a laboratory and commercial environment. Such a cell will have minimal bulk recombination due to a combination of a thin substrate with a very high minority carrier lifetime; superb surface passivation; small-area electrical contacts consistent with low contact recombination, free carrier absorption and contact resistance; excellent optical control through the use of texturing, antireflection coatings and rear surface reflectors; low edge recombination assisted by the use of thinner wafers, larger cells and edge passivation; and sufficient metal coverage to minimise resistive losses. This paper will survey current work in high- performance silicon solar cell design and fabrication, and discuss approaches to efficiency improvements.

Published

2013

40. Simplified Front Surface Field Formation for Back Contacted Silicon Solar Cells

Author

Andreas Wolf, Daniel Biro, Robert Woehl, Achim Kimmerle, and Publica

Subjects

Materials science, Silicon, Herstellung und Analyse von hocheffizienten Solarzellen, Analytical chemistry, chemistry.chemical_element, doping, back-contact, Pilotherstellung von industrienahen Solarzellen, phosphorus-diffusion, Energy(all), Saturation current, Dotierung und Diffusion, Diffusion (business), Kontaktierung und Strukturierung, Sheet resistance, Common emitter, Theory of solar cells, back-junction, business.industry, front-surface field, Doping, Silicium-Photovoltaik, chemistry, Optoelectronics, PV Produktionstechnologie und Qualitätssicherung, Industrielle und neuartige Solarzellenstrukturen, business, Short circuit

Abstract

We investigate the formation of deep Phosphorus diffusion profiles with low surface concentrations in one single diffusion step. Such processes are suited for front surface field formation for n-type back-contact back-junction (BC- BJ) silicon solar cells or p-type silicon solar cells with alternative metallization techniques. The deposition temperature allows accurate control of the sheet resistance whereas the temperature of the in-situ oxidation strongly influences the profile-depth and surface concentration. The newly developed process leads to low dark saturation current densities well below 30 fA/cm 2 on alkaline-textured surfaces and low short circuit current loss at the front side. Due to their depth and adjustable surface concentration, the obtained profiles are promising for front-surface- fields (FSF) and novel n-type emitters. A first implementation in BC-BJ solar cells with aluminum-alloyed emitter shows a good blue response of the solar cells and an improved efficiency compared to the reference process by 0.6% abs .

Published

2013

41. Highly efficient all-screen-printed back-contact back-junction silicon solar cells with aluminum-alloyed emitter

Author

Jonas Krause, Daniel Biro, Robert Woehl, and Filip Granek

Subjects

Thermal oxidation, Materials science, Silicon, Passivation, business.industry, back-junction, aluminum alloying, Metallurgy, chemistry.chemical_element, Quantum dot solar cell, back-contact, screen-printing, Polymer solar cell, law.invention, Monocrystalline silicon, chemistry, Energy(all), law, silicon solar cells, Solar cell, Optoelectronics, business, Common emitter, n-type

Abstract

All-screen-printed back-contact back-junction silicon solar cells with aluminum-alloyed emitter on n-type base material were fabricated and analyzed at Fraunhofer ISE PV-TEC. Three different process sequences are compared to each other. One process flow with shallow phosphorus profiles realizes cells with efficiencies of 19.7%. Using a long thermal oxidation, cells with deep driven-in phosphorus profiles (front and back surface field) were processed where solar cell efficiencies of 20.0% are realized. Both cell efficiencies are independently measured at Fraunhofer ISE CalLab on a designated area of 16.65 cm2. The specific contact resistivity of screen-printed and fired silver paste to silicon surfaces with different phosphorus profiles was determined in dependence of several firing conditions. The main developed features of the presented cell structure comprise the firing-stable front and rear passivation layers, the spiking-free passivation layer against aluminum and the deep driven-in phosphorus profile that can be contacted by silver screen-printing paste in a firing step.

Published

2011

42. High efficiency interdigitated back-contact c-Si solar cells

Author

Joaquim Puigdollers, Cristobal Voz, Ramon Alcubilla, Gema López, Eric Calle, David Carrió, Albert Orpella, Isidro Martín, Pedro A. Ortega, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, and Universitat Politècnica de Catalunya. MNT - Grup de Recerca en Micro i Nanotecnologies

Subjects

Solar cells, Fabrication, Materials science, Passivation, Open-circuit voltage, business.industry, Atomic layer deposition, Bateries solars, crystalline silicon, Energies::Energia solar fotovoltaica::Cèl·lules solars [Àrees temàtiques de la UPC], Nanotechnology, Surface finish, back-contact, Optoelectronics, Cèl·lules solars, Crystalline silicon, passivation, business, Short circuit, Common emitter

Abstract

In this work we describe a baseline fabrication process of interdigitated-back-contact c-Si(p) solar cells, which combines conventional diffusion oven stages to define base p+ and emitter n+ regions at the backside, with front surface passivation using atomic layer deposited Al 2 O 3 films on textured surfaces with random pyramids. Very low reflectance with outstanding surface recombination velocity values around 3 cm/s are achieved in our precursors. Fabricated solar cells reach efficiencies up to 20.3% (AM1.5G 1 kW/m2, T=25°C), with short circuit density J sc , open circuit voltage V oc and fill factor FF of 40.6 mA/cm2, 648 mV and 77.2% respectively.

Published

2015

43. Codiffusion sources and barriers for the assembly of back-contact back-junction solar cells

Author

Daniel Biro, Roman Keding, N.B. Tanvir, Sebastian Meier, Andreas Wolf, Holger Reinecke, Philip Rothhardt, and Publica

Subjects

Fabrication, Materials science, Doping, Analytical chemistry, Chemical vapor deposition, back-contact, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Pilotherstellung von industrienahen Solarzellen, Silicium-Photovoltaik, Co-Diffusion, Saturation current, Gaseous diffusion, PV Produktionstechnologie und Qualitätssicherung, Electrical and Electronic Engineering, Diffusion (business), Layer (electronics), Sheet resistance, n-type

Abstract

In this study, several diffusion sources are investigated, aiming at codiffusion for the fabrication of back-contact back-junction (BC-BJ) silicon solar cell. As a gaseous diffusion source, a POCl3-diffusion process is investigated, and for solid diffusion sources, phosphorus- and boron-doped silicate glass (PSG and BSG) deposited by the means of plasma-enhanced chemical vapor deposition are considered. The n+-doped areas diffused from a solid PSG layer allow for a precise adjustment of the sheet resistance $(R_{{\rm sh}})$ in the range of 40–400 Ω/sq, along with a dark saturation current density $(J_{o})$ of 55 fA/cm $^{2}$ . Subsequently, boron diffusion from solid BSG layer leads to p+-doped areas with high doping levels ( $R_{\rm sh}=$ 50 Ω/sq). However, gaseous POCl3 diffusion in combination with solid boron diffusion from the BSG layer can only be successfully performed if the BSG layer is protected with an SiO x layer. Furthermore, by adjusting the gas flows during POCl3 diffusion, n+-doped areas with $R_{{\rm sh}}$ in the range of 150– 300 Ω/sq are achieved. The corresponding surfaces feature $J_{o}$ values of 30 fA/cm $^{2}$ . The result of this study is a flexible codiffusion setup allowing for the efficient integration in advanced process chains of BC-BJ solar cells which results in the cell efficiencies well above above $\eta =$ 20%.

Published

2015

44. Cross testing electrically conductive adhesives and conductive back-sheets for the ECN back-contact cell and module technology

Author

W. Eerenstein, Kees Broek, M.J.H. Kloos, and Ian Bennett

Subjects

Power loss, Engineering, business.industry, MWT, Contact resistance, Electrically conductive, Mechanical engineering, Damp heat, back-contact, Electrically conductive adhesives, CBS, durability testing, Energy(all), Surface structure, conductive back-sheet foil, Adhesive, business, Electrical conductor, ECA, FOIL method

Abstract

ECN set up a cross testing project in which suppliers of electrically conductive adhesives (ECA) and conductive back-sheet (CBS) foils participated. In the component part of the project, combinations of adhesive and foil were characterised for peel strength and contact resistance. The separate components were tested on dot geometry (ECA) and surface structure (CBS). In the module manufacture and testing part, 12 combinations of ECA and CBS were used in 4-cell MWT modules. The modules were tested up to 2000 hours in damp heat and 400 thermal cycles (both tests, 2 times the requirement of IEC61215). Most combinations passed the 5% power loss criterion. One of the conductive adhesives performed well on three different types of back-sheet which is supportive of a robust technology. Other results show that it is important to thoroughly test interesting combinations of ECA and CBS at module level before adding them to the recommended bill of materials.

Published

2015

45. High efficiency interdigitated back-contact c-Si solar cells

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. MNT - Grup de Recerca en Micro i Nanotecnologies, Calle Martín, Eric, Ortega Villasclaras, Pablo Rafael, López Rodríguez, Gema, Martín García, Isidro, Carrió Díaz, David, Voz Sánchez, Cristóbal, Orpella García, Alberto, Puigdollers i González, Joaquim, Alcubilla González, Ramón, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. MNT - Grup de Recerca en Micro i Nanotecnologies, Calle Martín, Eric, Ortega Villasclaras, Pablo Rafael, López Rodríguez, Gema, Martín García, Isidro, Carrió Díaz, David, Voz Sánchez, Cristóbal, Orpella García, Alberto, Puigdollers i González, Joaquim, and Alcubilla González, Ramón

Abstract

In this work we describe a baseline fabrication process of interdigitated-back-contact c-Si(p) solar cells, which combines conventional diffusion oven stages to define base p+ and emitter n+ regions at the backside, with front surface passivation using atomic layer deposited Al2O3 films on textured surfaces with random pyramids. Very low reflectance with outstanding surface recombination velocity values around 3 cm/s are achieved in our precursors. Fabricated solar cells reach efficiencies up to 20.3% (AM1.5G 1 kW/m2, T=25°C), with short circuit density Jsc, open circuit voltage Voc and fill factor FF of 40.6 mA/cm2, 648 mV and 77.2% respectively., Postprint (published version)

Published

2015

46. Development and construction of a device related to a new structured metallization concept for back-contact crystalline silicon solar cells by using metal foil

Author

Mayer, Alexander Rui Pfaff and Neto, Pedro Mariano Simões

Subjects

células fotovoltaicas de alta eficiência, silício, high-efficiency solar cells, silicon, metalização, folha de aluminio, aplicação a laser, back-contact, metallization, laser applications, metal foil

Abstract

Dissertação de Mestrado Integrado em Engenharia Mecânica apresentada à Faculdade de Ciências e Tecnologia da Universidade de Coimbra

Published

2014

47. Numerical Simulation on the Influence of Via and Rear Emitters in MWT Solar Cells

Author

Paolo Magnone, Michel Frei, Enrico Sangiorgi, Claudio Fiegna, Marco Galiazzo, Raffaele De Rose, Mauro Zanuccoli, Andrea Belli, Diego Tonini, Paolo Magnone, Raffaele De Rose, Diego Tonini, Michel Frei, Mauro Zanuccoli, Andrea Belli, Marco Galiazzo, Enrico Sangiorgi, and Claudio Fiegna

Subjects

via, Materials science, business.industry, Schottky barrier, Schottky diode, simulation, Condensed Matter Physics, Metal–semiconductor junction, Schotty, Electronic, Optical and Magnetic Materials, law.invention, solar cell, Operating temperature, Photovoltaics, law, Solar cell, Back-contact, Optoelectronics, Electrical and Electronic Engineering, business, Photovoltaic, metal wrap through (MWT), Common emitter, Dark current

Abstract

In this paper, we analyze, by means of numerical simulations, metal wrap through (MWT) silicon solar cells without a rear emitter and/or via an emitter that feature a Schottky contact between the Ag metal and the p-base. We show how the effective Schottky barrier height affects both dark and illuminated properties of the cell. An equivalent electrical model for the dark analysis is proposed, which accounts for the shunting effects and the thermionic-emission current at Ag/p-base contact. We investigate the figures of merit of MWT solar cells for different via configurations, highlighting the influence of the Ag/p-base barrier height. Moreover, the influence of the rear busbar width, as well as of the operating temperature, is analyzed.

Published

2014

48. Numerical simulation and modeling of resistive and recombination losses in MWT solar cells

Author

Paolo Magnone, Enrico Sangiorgi, Michel Frei, Raffaele De Rose, Felice Crupi, Diego Tonini, Claudio Fiegna, Paolo Magnone, Diego Tonini, Raffaele De Rose, Michel Frei, Felice Crupi, Enrico Sangiorgi, and Claudio Fiegna

Subjects

via, Materials science, Busbar, law.invention, photovoltaic, Back-contact, metal wrap through (MWT), numerical simulation, photovoltaics, solar cell, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials, Condensed Matter Physics, law, Photovoltaics, Solar cell, Electronic, Optical and Magnetic Materials, Resistive touchscreen, Computer simulation, business.industry, Thermal conduction, Optoelectronics, Charge carrier, business, human activities, Technology CAD

Abstract

This study analyzes the impact of resistive and recombination losses in metal wrap through (MWT) solar cells through technology computer aided design (TCAD) numerical simulations. Two types of MWT architectures are considered in this study: “point busbar,” featuring one circular tabbing contact for each via at the back side, and “continuous busbar,” in which the rear busbar connects all the vias along a line. A comparison with conventional, H-pattern, front contact (FC) solar cells is performed by adopting the surface recombination velocity at the rear-contact isolation region as a parameter representative of possible passivation options. The differences under dark and light conditions are highlighted. Moreover, the following resistive losses in MWT cells are investigated: via resistance, shunting effect, and lateral conduction of charge carriers above rear busbar. An analytical model to account for the lateral conduction of charge carriers is proposed and validated by means of numerical simulations. While the advantage of MWT over FC cells is confirmed by simulation, we quantitatively show how the resistive and recombination losses limit the efficiency of MWT cells.

Published

2013

49. Front-floating Emitter Voltage Mapping of IBC Mercury Cells

Author

Agnes A. Mewe, Ard H. G. Vlooswijk, I. Cesar, N. Guillevin, Teun Burgers, Arthur Weeber, Pierpaolo Spinelli, and Bart Geerligs

Subjects

Engineering, business.industry, Busbar, Homogeneity (statistics), Front (oceanography), n-type, voltage mapping, back-contact, LBIC, IBC cells, Optics, Energy(all), Wafer, front floating emitter, business, Voltage, Common emitter

Abstract

Standard characterization techniques such as LBIC are difficult to apply to IBC solar cells with a front floating emitter (FFE). This is because the cells need to be under bias illumination, and this is often impossible in commercial LBIC measurement tools. To the best of our knowledge, LBIC measurements on FFE IBC cells have not been published so far. In this work we present a experimental method to spatially characterize the FFE of IBC cells and gain insights on electrical shading losses, without using LBIC. This method makes use of the commercially available CoreScan device, mapping the FFE voltage relative to the shorted back-contacts over the cell area. Using this technique we were able to resolve busbar, pads and finger features of both polarities with a scan of the front side. The scan shows that BSF features have higher voltage than emitter features, thus giving a direct evidence of the FFE pumping effect. If coupled to circuit simulation, FFE voltage maps can be the base for estimating electrical shading losses in IBC cells. The FFE voltage maps also give information on the homogeneity of the pumping effect across the wafer, e.g. affected by diffusion non-uniformity, and at least qualitatively its effect on the cell performance.

50. Continued Development of All-Back-Contact Silicon Wafer Solar Cells at ANU

Author

Johnson Wong, Qiang Huang, Teng Kho, Andrew Blakers, Armin G. Aberle, Keith R. McIntosh, Ngwe Zin, Xueling Zhang, Kean Fong Chern, Pierre J. Verlinden, Yang Yang, Zhiqiang Feng, Evan Franklin, and Thomas Mueller

Subjects

Materials science, Passivation, Equivalent series resistance, business.industry, Energy conversion efficiency, Nanotechnology, engineering.material, OPAL 2, Solar energy, Electrical shading loss, Energy(all), Coating, Saturation current, FSF, Photoconductance, engineering, Back-contact, Optoelectronics, Wafer, PC2D, business, Sheet resistance

Abstract

The collaboration between the Solar Energy Research Institute of Singapore (SERIS), Trina Solar and ANU is progressing well, and ANU has already developed all-back-contacted (ABC) silicon wafer cells with best one-sun efficiencies of 21.2% and 22.1% on FZ material, when measured with the aperture areas of 16 cm2 (includes busbars) and 13 cm2 (excludes busbars) respectively. This paper presents the continuing development of ABC cells targeting the efficiency of 23.5% on 16-cm2 cell area. Further developments such as optimising front surface field (FSF), rear diffusion, anti-reflection coating (ARC), and incorporation of lithographically aligned metal contacts were undertaken on the ABC cells. Phosphorus diffusion of the FSF was made lighter from the sheet resistance of 190 Ω/□ to 240 Ω/□, resulting in the reduction of the saturation current density ( Joe ) of the FSF by 22 fA/cm2. The optimised thickness of anti-reflection coating (ARC) PECVD SiNx further reduces the average reflectance across the wavelength range of 300 to 1200 nm by about 4%. Incorporation of aligned metal contacts and heavier rear phosphorus diffusion has contributed to the reduction in the total series resistance by 0.08 Ωcm2. The above optimised improvements have increased the efficiency of the champion ABC cell by 0.5% absolute. In addition, we present further refinements in areas of texturing; FSF passivation; electrical shading loss in terms of cell pitch, bus- bar and base doping; and metallisation to aim for the 16-cm2 ABC cells with the conversion efficiency > 22% in the near term.