Adil Sunny scite author profile

In this study, a hole transport layer (HTL)-free perovskite solar cell (PSC) structure with CH3NH3SnI3 as an active layer and TiO2 as an electron transport layer (ETL) has been proposed for the first time. The solar cell capacitance simulator in one dimension program has been carried out to design the proposed HTL-free CH3NH3SnI3-based PSC and simulate its performance. The output parameters of the proposed PSC, such as open circuit voltage (Voc), short-circuit current density (Jsc), fill factor (FF), power conversion efficiency, and quantum efficiency, are evaluated by varying the physical parameters of various layers. The thermal stability of the proposed cell has also been analyzed. The thicknesses of the ETL and the absorber are optimized to be 0.05 and 1.0 µm, respectively. A conversion efficiency of 26.33% along with Voc of 0.98 V, Jsc of 31.93 mA/cm2, and an FF of 84.34% is obtained for the proposed HTL-free CH3NH3SnI3-based PSC. These simulation results would be helpful in fabricating highly efficient and inexpensive PSCs.

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Numerical Simulation and Performance Evaluation of Highly Efficient Sb₂Se₃ Solar Cell with Tin Sulfide as Hole Transport Layer

Sunny

Ahmed

2021

Physica Status Solidi (b)

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This work reports a numerical investigation on the performance of Sb2Se3‐based thin‐film heterojunction solar cell using the solar cell capacitance simulator in 1D (SCAPS‐1D) program. Herein, inorganic tin sulfide (SnS) is introduced as a new hole transport material into the Sb2Se3 solar cell. The effects of several parameters such as thickness, doping, electron affinity, defect density, temperature, and resistances on the cell performances are analyzed. The proposed novel solar configuration that consists of Al/F:SnO2 (FTO)/CdS/Sb2Se3/SnS/Mo reveals the enhanced photovoltaic performances by means of reducing carrier recombination loss at back surface. At an optimized Sb2Se3 thickness of 1.0 μm, the efficiency is boosted from 24.01% to 29.89% by incorporating an ultrathin 0.05 μm SnS hole transport layer (HTL) into the Sb2Se3 solar cell. The performances of the proposed device are also evaluated by varying defects at CdS/Sb2Se3 and Sb2Se3/SnS interfaces. Moreover, it is found that electron affinity larger than 3.5 eV of HTL as well as back contact metal work function ≥4.9 eV should be considered to attain better performance. The simulated results lead to suggest that introducing the SnS material as a potential HTL candidate would be useful to develop low‐cost and highly efficient thin‐film solar cells.

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Performance evaluation of WS₂ as buffer and Sb₂S₃ as hole transport layer in CZTS solar cell by numerical simulation

Riyad

Sunny

Khatun

et al. 2022

Engineering Reports

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This study reports on performance enhancement of a Cu2ZnSnS4 solar cell introducing Sb2S3 as hole transport layer (HTL) along WS2 as buffer layer. We have investigated photovoltaic (PV) characteristics by utilizing SCAPS‐1D. A comparative analysis on PV performances between conventional CZTS/CdS and proposed Ni/Sb2S3/CZTS/WS2/FTO/Al solar cells is presented. It is revealed that “spike like” band structure at the CZTS/WS2 interface having smaller conduction band offset makes it potential alternative to commonly used CdS buffer. This report also evaluates that the Sb2S3 as an HTL inserted at the rear of CZTS enhances performances by reducing carrier recombination at back interface with appropriate band alignment. The impacts of thickness, carrier concentration of different layers, and bulk defect density in CZTS as well as the interface defects on cell outputs are analyzed. The influences of temperature, work function, and cell resistances are also examined. Optimum absorber thickness of 1.0 μm along doping density of 1017 cm−3 is selected. A maximum efficiency of 30.63% is achieved for the optimized CZTS cell. Therefore, these results suggest that Sb2S3 as HTL and WS2 as buffer layer can be employed effectively to develop highly efficient and low‐cost CZTS solar cells.

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Adil Sunny

Performance enhancement of Sb2Se3 solar cell using a back surface field layer: A numerical simulation approach

Numerical investigation on performance improvement of WS2 thin-film solar cell with copper iodide as hole transport layer

Numerical study of high performance HTL-free CH3NH3SnI3-based perovskite solar cell by SCAPS-1D

Numerical Simulation and Performance Evaluation of Highly Efficient Sb₂Se₃ Solar Cell with Tin Sulfide as Hole Transport Layer

Performance evaluation of WS₂ as buffer and Sb₂S₃ as hole transport layer in CZTS solar cell by numerical simulation

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Adil Sunny

Performance enhancement of Sb2Se3 solar cell using a back surface field layer: A numerical simulation approach

Numerical investigation on performance improvement of WS2 thin-film solar cell with copper iodide as hole transport layer

Numerical study of high performance HTL-free CH3NH3SnI3-based perovskite solar cell by SCAPS-1D

Numerical Simulation and Performance Evaluation of Highly Efficient Sb2Se3 Solar Cell with Tin Sulfide as Hole Transport Layer

Performance evaluation of WS2 as buffer and Sb2S3 as hole transport layer in CZTS solar cell by numerical simulation

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Numerical Simulation and Performance Evaluation of Highly Efficient Sb₂Se₃ Solar Cell with Tin Sulfide as Hole Transport Layer

Performance evaluation of WS₂ as buffer and Sb₂S₃ as hole transport layer in CZTS solar cell by numerical simulation