Toward quantum efficiency enhancement of kesterite nanostructured absorber: A prospective of carrier quantization effect

Sravani, L.; Routray, Soumyaranjan; Pradhan, K P

doi:10.1063/5.0013504

Cited by 28 publications

(14 citation statements)

References 41 publications

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“…Incorporation of lesser bandgap compared to bulk material provides the advantages to absorb more number of photons from the solar spectrum. [ 18,30,31 ] These interesting phenomena help researcher to achieve more than 42% efficiency theoretically. [ 32 ] In this work, two‐dimensionally confined quantum wells (QWs) are proposed as a nanostructure with bulk material.…”

Section: Introductionmentioning

confidence: 99%

“…[9][10][11][12][13][14][15][16][17] In addition to this, incorporation of nanostructure with carrier confinement increases the overall performance of solar cell as compared to bulk solar cell. [18][19][20][21] On the other hand, the performance of CFTS and CFTSe is less explored. The material possesses the capability to reduce defects and traps as compared to CZTS.…”

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confidence: 99%

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Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Varku

Pradhan

Routray

2022

Physica Status Solidi (a)

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In recent times, research communities are working on device to harvest solar energy at low cost. Copper‐based quaternary chalcogenides are one among the leading materials in the field. Herein, the electrical and optical performance of quantum well embedded Cu 2 - Fe - Sn - normalS 4 (CFTS) solar cell is investigated in detail. Multiple quantum wells (MQWs) with different bandgaps ensure wider photon absorption of solar spectrum. Hence, MQWs made up of CFTSe/CFTS are incorporated with a variation in well size and well numbers. All the electrical parameters and optical parameters such as power conversion efficiency, quantum efficiency, and its dependence on carrier quantization are discussed in detail. More than 80% external quantum efficiency with just 2 QWs shows the efficient carrier generation and collection of the proposed structure. Device with 10 QWs of size 18/10 nm of CFTSe/CFTS can achieve remarkable efficiency of 21% with good trade‐off between J sc and fill factor.

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Varku

Pradhan

Routray

2022

Physica Status Solidi (a)

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“…The detailed description of models and equations used in this study can be found in the supplementary material. [ 16 ] Silvaco ATLAS technology computer‐aided design (TCAD) tool is used to analyze the functioning and performance of these photovoltaic devices. [ 17 ] The simulation of these devices is carried out under an illumination spectrum power of 1 sun with air mass 1.5 global spectrum.…”

Section: Introductionmentioning

confidence: 99%

“…All the mathematical expressions for four performance measuring parameters with only traps and only defects can be found in the previous studies. [ 8,16 ] The reverse saturation current density is calculated, considering non‐radiative recombination, the presence of defects states, and trap states. Shockley–Read–Hall (SRH) recombination mechanism is applied to incorporate the effect of trap states near the middle of the forbidden gap.…”

Section: Introductionmentioning

confidence: 99%

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Kesterite Thin‐Film Solar Cell: Role of Grain Boundaries and Defects in Copper–Zinc–Tin–Sulfide and Copper–Zinc–Tin–Selenide

Sravani

Routray

Pradhan

et al. 2021

Physica Status Solidi (a)

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Kesterite materials, such as copper–zinc–tin–sulfide (CZTS) solar cell, have received considerable attention for low‐cost and high‐efficiency solar cells. However, the material suffers from poor quality of thin film during deposition, which, in turn, creates multiple grain boundaries along the layer. Consequently, a higher density of defects is randomly formed throughout the layer. Herein, the impact of different loss mechanisms on solar cell performance is analyzed. Numerical investigation on the influence of different loss mechanisms such as radiative recombination and recombination through traps and defects on the performance of the device is presented. A remarkable efficiency decrement of 10% in the devices is found due to the presence of defects and grain boundaries.

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Analyzing the Effect of Planar and Inverted Structure Architecture on the Properties of MAGeI₃ Perovskite Solar Cells

Jan,

Noman

2023

Energy Tech

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CTL have remarkable influence on the stability and efficiency of PSC. Different CTL combination used with the perovskite forms unique energy band alignment and electric field. They have significant effects on the optoelectrical properties of PSC. Identifying the right CTL for perovskite is crucial. In this work, the PSC of CH3NH3GeI3 are modeled in SCAPS‐1D with 13 CTL. Because of their high carrier‐mobility, chemical‐stability, and excellent electric/thermal conductivity, copper, kesterite and carbon CTL have been selected. The PSC was analyzed in planar(n‐i‐p) and inverted(p‐i‐n). A systematic approach has been adopted to analyze the influence of CTL on the quantum‐efficiency, absorption, transmissivity, band‐alignment, electric‐field, recombination, and IV‐characteristics in both architectures. To further enhance the efficiency, design optimization of layer thickness and doping has been carried‐out. Moreover, the effect of defects, temperature, reflection, and front/back workfunctions on the performance of PSC has also been studied. Based on the results PCBM performed better in planar while C60 performed better in inverted. Most of the Cu‐HTL performed better in inverted architecture while most of the kesterite‐HTLs performed better in planar architecture. The best‐performing inverted perovskite structures was PCBM/Per/CuAlO2 with PCE of 24.32 %, while the best planar structure was C60/Per/CuAlO2 with PCE of 14.82 %.This article is protected by copyright. All rights reserved.

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Toward quantum efficiency enhancement of kesterite nanostructured absorber: A prospective of carrier quantization effect

Cited by 28 publications

References 41 publications

Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Kesterite Thin‐Film Solar Cell: Role of Grain Boundaries and Defects in Copper–Zinc–Tin–Sulfide and Copper–Zinc–Tin–Selenide

Analyzing the Effect of Planar and Inverted Structure Architecture on the Properties of MAGeI₃ Perovskite Solar Cells

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Toward quantum efficiency enhancement of kesterite nanostructured absorber: A prospective of carrier quantization effect

Cited by 28 publications

References 41 publications

Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Retrieving Carrier Population and Collection Efficiency in CFTS/CFTSe‐Based Solar Cell Using Low‐Dimensional Multiple Nanostructures

Kesterite Thin‐Film Solar Cell: Role of Grain Boundaries and Defects in Copper–Zinc–Tin–Sulfide and Copper–Zinc–Tin–Selenide

Analyzing the Effect of Planar and Inverted Structure Architecture on the Properties of MAGeI3 Perovskite Solar Cells

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Analyzing the Effect of Planar and Inverted Structure Architecture on the Properties of MAGeI₃ Perovskite Solar Cells