Integration of buildings with third-generation photovoltaic solar cells: a review

Mirabi, Elahe; Abarghuie, Fatemeh Akrami; Arazi, Rezvan

doi:10.1093/ce/zkab031

Cited by 18 publications

(6 citation statements)

References 255 publications

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“…Smaller solar panels are needed to get the same output; hence, the increased efficiency of >30% significantly contributed to reduced prices. The many types of third-generation photovoltaics have been separated into three distinct categories [11].…”

Section: Third-generation Solar Cellsmentioning

confidence: 99%

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

Santosh Kumar Srivastava,

Jitendra Singh

2023

IJSRMST

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Thin-film Silicon (Si) Solar Cells (SCs) have emerged as a promising candidate for next-generation photovoltaic devices due to their potential for cost-effectiveness and versatility. However, achieving high efficiency and long-term stability remains a significant challenge in their development. The primary challenges with thin-film Si SCs have been the poor infrared light absorption of Hydrogenated Microcrystalline Silicon (c-Si: H) and the light-induced metastability of Hydrogenated Amorphous Silicon (a-Si: H). This study reviewed the influence of the p-type layer, a key component in thin-film Si SCs, on both performance and stability. Third generation SCs are optimized for high Power Conversion Efficiency (PCE) at low manufacturing costs. According to the review of the comparison analysis, Patel K. et al., (2021) obtained the highest PCE of 30.17% with the a-Si/MoTe2 material (Photocurrent Density Jsc = 32.41mA/cm2, An Open-Circuit Voltage Voc = 1.093V, and Fill Factor (FF) = 85.12%) of the state-of-the-art previous works. The findings presented here contribute valuable insights toward the development of efficient and durable SC technology, crucial for advancing the adoption of renewable energy sources in our ever-growing energy demand.

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Section: Third-generation Solar Cellsmentioning

confidence: 99%

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

Santosh Kumar Srivastava,

Jitendra Singh

2023

IJSRMST

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“…New aesthetic possibilities are brought by the development of the third--generation cell technology, which in a way emerged in response to aesthetic and pro-environmental needs. As yet, these solutions remain, however, not competitive enough in terms of efficiency or durability (Pastuszak&Węgierek, 2022;Park, 2015), despite the enormous progress in recent years (Mirabi et al, 2021).…”

Section: B Artistic Effectsmentioning

confidence: 99%

Aesthetic and functional aspects of BIPV – an architectural outlook

Marchwiński

2023

TechTrans

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The growing interest in the application of photovoltaics in construction resultsin solutions based on the concept of integration with the architecture of thebuilding. This means that the challenge lies not only in the technical integrationitself but in accordance with the concept of building integrated photovoltaics(BIPV), integration results in closer ties with architecture.The following article aims to determine the current possibilities with regard tothe integration of PV technology with the building (narrowed down to the useof PV cells and PV modules) and, consequently, the role of BIPV in modernarchitecture in terms of aesthetics and functionality, including the relationship ofthe building with the environment. The paper offers an architectural perspectiveon the problem while omitting detailed technological issues.To illustrate the considerations, carefully selected design examples (includingthose developed by the author) are used, which enable these possibilities to bedefined across a broad spectrum.Research prompts the conclusion that the development of biPv strengthensthe relationship between Pv technology and architecture, both in terms ofaesthetics and utility. This relationship is synergistic and stimulates the paralleldevelopment of Pv technology as architectural solutions.

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“…Cu(In,Ga)Se 2 (CIGSe) thin‐film solar cells present an opportunity for flexible, tandem, or semitransparent applications, together with easy and cheap manufacturing for large‐area modules due to milder processing temperatures compared to silicon solar cells. [ 1–4 ] This technology has been widely studied because CIGSe can be prepared by several methods that give high control over its properties, notably its tunable bandgap (1.0–1.7 eV), [ 5,6 ] and high absorption coefficient (>10 5 cm −1 ) [ 5,6 ] with a record power conversion efficiency (PCE) of 23.4% achieved by SolarFrontier. [ 7 ]…”

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Chemical Bath Deposition of Zn_1−xSn_xO_y Films as Buffer Layers for Cu(In,Ga)Se₂ Solar Cells

et al. 2023

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Cu(In,Ga)Se 2 (CIGSe) thin-film solar cells present an opportunity for flexible, tandem, or semitransparent applications, together with easy and cheap manufacturing for large-area modules due to milder processing temperatures compared to silicon solar cells. [1][2][3][4] This technology has been widely studied because CIGSe can be prepared by several methods that give high control over its properties, notably its tunable bandgap (1.0-1.7 eV), [5,6] and high absorption coefficient (>10 5 cm À1 ) [5,6] with a record power conversion efficiency (PCE) of 23.4% achieved by SolarFrontier. [7] A key component in CIGSe solar cells is the buffer layer, which forms the chargeseparating pn-junction with the absorber and provides a good electrical and optical interface with the front contact layers, ensuring charge carrier transport, and minimal interface recombination. CdS deposited by chemical bath deposition (CBD) is the traditional buffer material due to its electrical and structural matching with the absorber. [8] This n-type material only yields high-efficiency solar cells when it is deposited by CBD, due to the action of ammonia on the surface of CIGSe and the complete and conformal coverage over the polycrystalline CIGSe. [9] The CBD technique consists of the deposition of inorganic (oxide, sulfide, or selenide) thin films by immersion of a substrate in a precursor solution. It is based on a controlled chemical reaction (normally hydrolysis) performed typically in an aqueous solution that yields coating of the substrate (heterogeneous nucleation at the solution/substrate interface) while also resulting in a colloidal suspension (homogeneous nucleation occurring in solution). Generally, the precursor aqueous solution involves a soluble metal salt, a pH agent, and a complexing agent, used to control the hydrolysis rate.However, the relatively low direct bandgap of CdS, E g = 2.4-2.5 eV, [10] prevents high energy photons from being absorbed by the p-CIGSe. [11] In addition, the presence of toxic Cd presents health and environmental concerns. [12,13] Therefore, wider bandgap and less toxic materials have been researched to produce Cd-free CIGSe solar cells. [11,14,15] Among these materials, zinc tin oxide (Zn 1Àx Sn x O y , ZTO) has attracted much attention due to its nontoxicity, fast light responsivity, and tunable wide bandgap. CIGSe solar cells based on ZTO buffers have resulted in PCE comparable to or even higher than CdS ones. [8,11,14,16] Until now, ZTO buffer layers on CIGSe solar cells have been only fabricated by atomic layer deposition (ALD) with atomically precise resolution in vacuum conditions by sequential vapor reactions of organometallic precursors and gases. Although ALD allows excellent control over ZTO composition and assures excellent coverage, [17] it is hardly scalable, time-consuming, and expensive. In contrast, the production of record CIGSe-based solar cells makes use of the CBD to produce CdS and other inorganic thin

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Integration of buildings with third-generation photovoltaic solar cells: a review

Cited by 18 publications

References 255 publications

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

Aesthetic and functional aspects of BIPV – an architectural outlook

Chemical Bath Deposition of Zn_1−xSn_xO_y Films as Buffer Layers for Cu(In,Ga)Se₂ Solar Cells

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Integration of buildings with third-generation photovoltaic solar cells: a review

Cited by 18 publications

References 255 publications

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

The Impact of P-Type Layer on Performance and Stability of Thin Film Silicon Solar Cells in Relation to Third Generation: A review Analysis

Aesthetic and functional aspects of BIPV – an architectural outlook

Chemical Bath Deposition of Zn1−xSnxOy Films as Buffer Layers for Cu(In,Ga)Se2 Solar Cells

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Chemical Bath Deposition of Zn_1−xSn_xO_y Films as Buffer Layers for Cu(In,Ga)Se₂ Solar Cells