Size and grain-boundary effects on the performance of polycrystalline CIGS-based solar cells

Bouchama, Idris; Rafik, Zouache; Djessas, K.; Abdessalam, Bouloufa; Ghribi, Faouzi

doi:10.1109/irec.2015.7110920

Cited by 5 publications

(3 citation statements)

References 14 publications

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“…[46][47][48] The process also enlarges grain size, which effectively decreases grain boundary concentration, potentially boosts carrier mobility, reduces the chance of electron-hole recombination, and subsequently increases current generation. [49][50][51] The next section discusses the development of a molecular-based approach for CIGSe PV devices using the thiol-amine solvent combination. Table I summarizes the recent PV performance of processed CIGSe thin-film devices fabricated using the thiol-amine route.…”

mentioning

confidence: 99%

Review—Solution Processing of CIGSe Solar Cells Using Simple Thiol-Amine Solvents Mixture: A Review

Albalawneh¹,

Ramli²

2020

ECS J. Solid State Sci. Technol.

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Recent results demonstrate the potential of thiol-amine binary solvents to prepare highly efficient thin-film chalcopyrite photovoltaic devices. The power of these solvent mixtures lies in their ability to dissolve a large variety of metal and metal chalcogenide precursors and their ease of application in low-temperature solution-based deposition techniques. This review recounts the early reports that revealed the flexibility and broad ability of the thiol-amine solvent system, and the chemistry behind these solvents. Next, the resulting CIGSe films PV devices fabricated using amine-thiol solution processing techniques are being introduced and analyzed in detail. Finally, Current challenges, as well as prospects for effective technology implementation, were discussed.

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mentioning

confidence: 99%

Review—Solution Processing of CIGSe Solar Cells Using Simple Thiol-Amine Solvents Mixture: A Review

Albalawneh¹,

Ramli²

2020

ECS J. Solid State Sci. Technol.

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“…This was suggested to be due to the formation of different defects in grain boundaries, both donor and acceptor type that create a potential well in the band structure, though the width of these wells was found to be around 1-2 nm. Grain boundaries were also studied with simulation tools, such as in [Idris, 2015], in which a CIGS solar cell with a grain boundary is simulated. Different properties related to the grain boundary, such as the width of the grain or the width of the grain boundary were varied, and it was found that larger grain sizes correlate with increased efficiencies while larger grain boundary widths are related to lower efficiencies [Idris, 2015].…”

Section: Performance Loss Mechanisms In Cellsmentioning

confidence: 99%

“…Grain boundaries were also studied with simulation tools, such as in [Idris, 2015], in which a CIGS solar cell with a grain boundary is simulated. Different properties related to the grain boundary, such as the width of the grain or the width of the grain boundary were varied, and it was found that larger grain sizes correlate with increased efficiencies while larger grain boundary widths are related to lower efficiencies [Idris, 2015].…”

Section: Performance Loss Mechanisms In Cellsmentioning

confidence: 99%

Characterization and simulation of CIGS thin-film solar cells and interconnects

Lorbada¹

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Prospects of photovoltaic solar energy have improved in the recent years, due to the aim of global actors to increase the ratio of green energy produced. In the market of photovoltaics, thin-film solar cells based on Cu(In,Ga)(Se,S)2 material, (the cells under study in this thesis do not include Sulphur, and the material is known in short as CIGS) are a well-established technology that conjugates the advantages of thin-film devices with abundant and non-toxic materials, in contrast with other thin-film technologies based on toxic cadmium and the somewhat scarce tellurium. Another promising characteristic of this technology is found in the recent achievements in efficiency that put CIGS devices on par with multi-crystalline silicon solar cells. However, this technology presents some issues regarding its performance that may disadvantage it with respect to the other well-stablished technologies. Although the efficiency of the best laboratory scale solar cell based on CIGS is now close to that of multi-crystalline Si, there is still room for improvement of absorber and interface properties; the efficiency of commercial modules is also still behind that of the best lab-scale device due to performance losses introduced by the interconnection between cells. Moreover, this material also suffers from a somewhat poorer stability against certain operation conditions that are typically found in PV installations such as light-soaking or reversebiasing of cells due to shading for instance. The most devastating condition is known as potential induced degradation, which affects the performance dramatically and might result in warranty breaching for the manufacturer, reducing the economic attractiveness of this technology.The poorer performance and stability of CIGS technology can only be addressed with a good understanding of the electronic properties of the devices. The aim of this work is to provide knowledge on certain issues that affect the performance and stability of CIGS solar cells. The first issue is the impact of the interconnection between cells on the performance of the device. The scribing process that divides the module in cells results in three trenches (named as P1, P2 and P3) with different purposes. The first trench (P1) separates the back-contact of two adjacent cells, the second trench (P2) connects the front contact of a cell with the back-contact of the next adjacent cell and the third trench (P3) separates the front contact of two adjacent cells. Nonetheless, the P1 trench is typically filled with absorber material (CIGS), which does not provide a perfect isolation and may result in a significant shunt. The impact of the P1 shunt is studied in this thesis with 2D simulations and the characterization of devices (I-V, imaging techniques and C-V) with interconnection, considering the properties of the absorber, and an equivalent circuit model, based on a Junction Field-Effect Transistor is proposed to represent the behavior of the P1 shunt. Metastable changes in the absorber (that are typical of CIGS devices...

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Device modeling and performance analysis of an all-inorganic lead-free Ag2BiI5 rudorffite-based solar cell with AgSCN as HTL via GPVDM simulation software

Mozaffari

2024

J Comput Electron

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Size and grain-boundary effects on the performance of polycrystalline CIGS-based solar cells

Cited by 5 publications

References 14 publications

Review—Solution Processing of CIGSe Solar Cells Using Simple Thiol-Amine Solvents Mixture: A Review

Review—Solution Processing of CIGSe Solar Cells Using Simple Thiol-Amine Solvents Mixture: A Review

Characterization and simulation of CIGS thin-film solar cells and interconnects

Device modeling and performance analysis of an all-inorganic lead-free Ag2BiI5 rudorffite-based solar cell with AgSCN as HTL via GPVDM simulation software

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