Passivation of Deep-Level Defects by Cesium Fluoride Post-Deposition Treatment for Improved Device Performance of Cu(In,Ga)Se<sub>2</sub> Solar Cells

Lee, Ho-Jin; Jang, Young‐Il; Nam, Sung-Wook; Jung, Chanwon; Choi, Pyuck‐Pa; Gwak, Jihye; Yun, Jae Ho; Kim, Kihwan; Shin, Byungha

doi:10.1021/acsami.9b08316

Cited by 41 publications

(50 citation statements)

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“…Note that the K atoms incorporated in the CIGS film are expected to accumulate at the CdS/CIGS interface and CIGS grain boundaries, which passivate defects and provide doping characteristics to the CIGS absorber layer. [ 17,19,20 ] The BK‐CIGS device shows a decreasing hole concentration in comparison to the U‐CIGS and SK‐CIGS devices as shown in the C – V results (Figure 6a), which seems to be an opposite trend of increasing hole carrier density, often reported in the literature. [ 31,55 ] Although there might exist K involved defects, likely, defect passivation and p‐doping do not significantly occur in these K incorporated devices.…”

Section: Resultsmentioning

confidence: 61%

“…To improve the performance of CIGS solar cells fabricated through vacuum processing, alkali metal (AM) atoms are commonly incorporated on the CIGS surface through post-deposition treatment (PDT). [14][15][16][17][18][19][20][21][22][23][24][25] Such treatment has recently resulted in efficiencies as high as ≈23%. [15,16] While light AM atom such as sodium (Na) diffuses into grain interior and changes doping concentration, [17,19] heavier AM atoms like potassium (K), rubidium (Rb), and cesium (Cs) tend to form a segregated secondary phase (AM-In-Se) at the grain boundaries and CdS/ CIGS interface, [17,18] and this passivates defects.…”

Section: Introductionmentioning

confidence: 99%

“…[15,16] While light AM atom such as sodium (Na) diffuses into grain interior and changes doping concentration, [17,19] heavier AM atoms like potassium (K), rubidium (Rb), and cesium (Cs) tend to form a segregated secondary phase (AM-In-Se) at the grain boundaries and CdS/ CIGS interface, [17,18] and this passivates defects. [17][18][19][20][21] Besides, the AM-In-Se phase at the CdS/CIGS interface widens the bandgap and enhances charge selectivity. [22,23] Also, AM PDT reduces the CdS thickness by promoting Cd interdiffusion, and this reduces the current loss due to CdS parasitic absorption.…”

Section: Introductionmentioning

confidence: 99%

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Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Kim

Gadisa

et al. 2020

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Solution‐processed Cu(In,Ga)(S,Se)2 (CIGS) has a great potential for the production of large‐area photovoltaic devices at low cost. However, CIGS solar cells processed from solution exhibit relatively lower performance compared to vacuum‐processed devices because of a lack of proper composition distribution, which is mainly instigated by the limited Se uptake during chalcogenization. In this work, a unique potassium treatment method is utilized to improve the selenium uptake judiciously, enhancing grain sizes and forming a wider bandgap minimum region. Careful engineering of the bandgap grading structure also results in an enlarged space charge region, which is favorable for electron–hole separation and efficient charge carrier collection. Besides, this device processing approach has led to a linearly increasing electron diffusion length and carrier lifetime with increasing the grain size of the CIGS film, which is a critical achievement for enhancing photocurrent yield. Overall, 15% of power conversion efficiency is achieved in solar cells processed from environmentally benign solutions. This approach offers critical insights for precise device design and processing rules for solution‐processed CIGS solar cells.

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Section: Resultsmentioning

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Kim

Gadisa

et al. 2020

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“…It has been suggested that Cs reduces deep donor‐like defects (V Se and In Cu ) as well as deep‐level acceptor‐like defects (V In or Cu In ) and increases p ‐type characterization. 65 This, in turn, increases N CV .…”

Section: Resultsmentioning

confidence: 96%

Temperature‐dependent current–voltage and admittance spectroscopy analysis on cesium‐treated Cu (In_{1 − x},Ga_x)Se₂ solar cell before and after heat‐light soaking and subsequent heat‐soaking treatments

Khatri

Lin

Yashiro

et al. 2020

Progress in Photovoltaics

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Recently, we demonstrated the positive effects of heat-light soaking (HLS) and subsequent heat-soaking (HS) on cesium fluoride (CsF) treated Cu(In 1x, Ga x)Se 2 (CIGS) solar cells. However, the role of defects formation and its influence on the electronic properties have not been analyzed. With this motivation, here, we analyzed the electronic properties of CsF-free and CsF-treated CIGS solar cells before and after HLS and subsequent HS treatments using temperature-dependent current-voltage (J-V-T), admittance and low-temperature capacitance-voltage (C-V) measurements. We noticed that CsF-treated CIGS solar cells form a minority carrier trap level after HLS. The subsequent HS treatment was found to be beneficial to compensate this defect level. The admittance measurement showed a shift of the shallow energy position to a higher value after HLS and subsequent HS treatments, irrespective of Cs incorporation. This is expected to be due to the formation of a secondary diode toward the CIGS/molybdenum contact. The positive and negative effects of HLS and subsequent HS treatments on CsF-treated CIGS solar cell are discussed using low-temperature C-V measurements. By optimizing the HLS and HS processes, CsF-treated CIGS solar cells yielded total efficiencies of over 20%.

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“…[ 41,42 ] It was reported that F - can drift between lattice defects due to its very small ionic radius compared with other reported elements, which theoretically has the potential to fill the interstice, to mediate the perovskite crystallization, and to passivate deep‐level defects in hybrid perovskite system. [ 43–45 ] Moreover, incorporating fluorine could also strengthen the hydrophobicity of the resulting materials. Therefore, fluorine was chosen to tailor the crystallization process of CsPbI 2 Br in this study.…”

Section: Resultsmentioning

confidence: 99%

Multilayer Cascade Charge Transport Layer for High‐Performance Inverted Mesoscopic All‐Inorganic and Hybrid Wide‐Bandgap Perovskite Solar Cells

Chen

Tang

et al. 2020

Solar RRL

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The certified laboratory power conversion efficiency (PCE) of 25.2% has recently been achieved for hybrid organic-inorganic lead halide perovskite solar cells (PSCs), [1-5] which is now on par with that of the traditional photovoltaic (PV) devices. Despite their high efficiencies, the intrinsic volatility and thermal instability of organic components in hybrid perovskites are considered to be the important factors that limit their practical applications of PSCs. [6,7] As a potential solution to overcome the shortage of hybrid PSCs, allinorganic perovskites (CsPbX 3 , X ¼ Cl, Br, I, or mixed) have been developed in recent years. [8-10] Among them, mixedhalide inorganic perovskites, CsPbI 2 Br, feature excellent thermal stability and suitable direct bandgap (1.92 eV) for potential usage in tandem solar cells, and have gained increased attentions. [11,12] Much efforts have been dedicated to boost the PCEs of normal structured (n-i-p) CsPbI 2 Br PSCs to over 16% via interfacial engineering, crystallization tailoring, ion substitution, and/or doping of the perovskite. [13,14] Nevertheless, the PCEs for CsPbI 2 Br PSCs still lag far behind that of the hybrid PSCs, especially for the inverted structured devices (the latest developments for inverted CsPbI 2 Br PSCs are shown in Table S1, Supporting Information). [15] Compared with the n-i-p structured device, the development of inverted (p-in) structured PSCs is quite attractive and has recently drawn ever-increasingly research interests [16,17] because it can not only avoid using the unstable hole transport layers (HTLs), such as Spiro-OMeTAD (where 4-tert-butyl pyridine and lithium salts were traditionally adopted as the dopants), but also be more compatible with tandem solar cells. Up to date, most of the perovskite/perovskite tandem solar cells are fabricated with the p-in structures. [18,19] However, the development of inverted wide-bandgap PSCs remains limited. Therefore, it is highly desirable to develop novel strategies for high-efficiency inverted wide-bandgap PSCs. It is well known that the key factors influencing the overall device efficiency should be: 1) the film quality of all functional layers, especially for light absorber and charge transport layers (CTLs); 2) optoelectronic properties of CTLs, such as bandgaps, carrier mobility, and energy levels. [20-23] Therefore, obtaining high-quality perovskite film with reduced defects is the prerequisite for high-performance solar cells. Thus, far ion doping, such as Eu 2þ , [24] Mn 2þ , [25] Nb 5þ , [26] Cu 2þ , [27] Cl À , [25] and Br À , [28] has been proven to be an effective strategy to obtain large grains and in situ strengthen original octahedral structural stability in

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Passivation of Deep-Level Defects by Cesium Fluoride Post-Deposition Treatment for Improved Device Performance of Cu(In,Ga)Se₂ Solar Cells

Cited by 41 publications

References 43 publications

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Temperature‐dependent current–voltage and admittance spectroscopy analysis on cesium‐treated Cu (In_{1 − x},Ga_x)Se₂ solar cell before and after heat‐light soaking and subsequent heat‐soaking treatments

Multilayer Cascade Charge Transport Layer for High‐Performance Inverted Mesoscopic All‐Inorganic and Hybrid Wide‐Bandgap Perovskite Solar Cells

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Passivation of Deep-Level Defects by Cesium Fluoride Post-Deposition Treatment for Improved Device Performance of Cu(In,Ga)Se2 Solar Cells

Cited by 41 publications

References 43 publications

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)2 Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)2 Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Temperature‐dependent current–voltage and admittance spectroscopy analysis on cesium‐treated Cu (In1 − x,Gax)Se2 solar cell before and after heat‐light soaking and subsequent heat‐soaking treatments

Multilayer Cascade Charge Transport Layer for High‐Performance Inverted Mesoscopic All‐Inorganic and Hybrid Wide‐Bandgap Perovskite Solar Cells

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Product

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About

Passivation of Deep-Level Defects by Cesium Fluoride Post-Deposition Treatment for Improved Device Performance of Cu(In,Ga)Se₂ Solar Cells

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Morphological–Electrical Property Relation in Cu(In,Ga)(S,Se)₂ Solar Cells: Significance of Crystal Grain Growth and Band Grading by Potassium Treatment

Temperature‐dependent current–voltage and admittance spectroscopy analysis on cesium‐treated Cu (In_{1 − x},Ga_x)Se₂ solar cell before and after heat‐light soaking and subsequent heat‐soaking treatments