Investigation of the impact of different ARC layers using PC1D simulation: application to crystalline silicon solar cells
Copyright policy )Investigation of the impact of different ARC layers using PC1D simulation: application to crystalline silicon solar cells
En este trabajo, se ha investigado el impacto de seis capas diferentes de recubrimiento antirreflectante (ARC) utilizando el software de simulación PC1D. La simulación muestra que el rango de 500–700 nm sería adecuado para diseñar un ARCO. Diseñando un ARCO de nitruro de silicio de una sola capa (Si3N4) para una longitud de onda de 600 nm y con un espesor de 74.257 nm, se ha simulado una célula solar de silicio con una eficiencia del 20.35%. Le sigue muy de cerca una célula solar de silicio con una eficiencia del 20,34% con una capa de ARCO de óxido de zinc (ZnO) de 74,87 nm de espesor. Se ha observado un aumento significativo en la eficiencia al aplicar ARC con respecto a no aplicar ningún tipo de ARC. Después de un modelado eficiente de las células solares, se está logrando una eficiencia óptima del 20,67% mediante el uso de la pasivación superficial de SiO2 y la capa de ARCO de Si3N4. Los efectos sobre la tensión, la corriente, la eficiencia fotovoltaica, la reflectividad y la eficiencia cuántica externa debidos a los ARC también están representados en este trabajo.
Dans ce travail, l'impact de six couches différentes de revêtement antireflet (ARC) a été étudié à l'aide du logiciel de simulation PC1D. La simulation montre que la plage de 500–700 nm serait appropriée pour concevoir un ARC. En concevant un ARC de nitrure de silicium monocouche (Si3N4) pour une longueur d'onde de 600 nm et une épaisseur de 74,257 nm, une cellule solaire en silicium avec une efficacité de 20,35% a été simulée. Très étroitement suivie par une cellule solaire en silicium à 20,34 % d'efficacité avec une couche d'ARC en oxyde de zinc (ZnO) de 74,87 nm d'épaisseur. Une augmentation significative de l'efficacité a été observée en appliquant L'ARC par rapport à l'absence d'application de tout type d'ARC. Après une modélisation efficace des cellules solaires, une efficacité optimale de 20,67 % est obtenue en utilisant la passivation de surface SiO2 et la couche D'ARC Si3N4. Les effets sur la tension, le courant, l'efficacité photovoltaïque, la réflectivité et l'efficacité quantique externe dus aux ARC sont également représentés dans ce travail.
In this work, the impact of six different anti-reflection coating (ARC) layers has been investigated using PC1D simulation software. Simulation shows that the range of 500–700 nm would be suitable for designing an ARC. Designing a single-layer silicon nitride (Si3N4) ARC for 600 nm wavelength and with a thickness of 74.257 nm, a silicon solar cell with 20.35% efficiency has been simulated. Very closely followed by a 20.34% efficient silicon solar cell with 74.87 nm thick zinc oxide (ZnO) ARC layer. Significant increase in efficiency has been observed by applying ARC in respect to not applying any kind of ARC. After efficient solar cell modeling, optimum efficiency of 20.67% is being achieved by using SiO2 surface passivation and Si3N4 ARC layer. The effects on voltage, current, photovoltaic efficiency, reflectivity and external quantum efficiency due to ARCs are also represented in this work.
في هذا العمل، تم التحقيق في تأثير ست طبقات مختلفة من الطلاء المضاد للانعكاس (ARC) باستخدام برنامج محاكاة PC1D. تظهر المحاكاة أن النطاق من 500–700 نانومتر سيكون مناسبًا لتصميم القوس. تصميم قوس نيتريد السيليكون أحادي الطبقة (Si3N4) بطول موجي 600 نانومتر وبسمك 74.257 نانومتر، تمت محاكاة خلية شمسية من السيليكون بكفاءة 20.35 ٪. تليها عن كثب خلية شمسية من السيليكون فعالة بنسبة 20.34 ٪ مع طبقة قوسية من أكسيد الزنك بسماكة 74.87 نانومتر (ZnO). لوحظت زيادة كبيرة في الكفاءة من خلال تطبيق القوس فيما يتعلق بعدم تطبيق أي نوع من القوس. بعد نمذجة الخلايا الشمسية بكفاءة، يتم تحقيق الكفاءة المثلى بنسبة 20.67 ٪ باستخدام تخميل سطح SiO2 وطبقة Si3N4 القوسية. يتم تمثيل التأثيرات على الجهد والتيار والكفاءة الكهروضوئية والانعكاسية والكفاءة الكمية الخارجية بسبب ARCs أيضًا في هذا العمل.
- Bangladesh Atomic Energy Commission Bangladesh
- Bangladesh Atomic Energy Commission Bangladesh
- University of Dhaka Bangladesh
- University of Dhaka Bangladesh
Silicon nitride, Composite material, Surface passivation, Silicon, Surface Recombination, QC1-999, Biomedical Engineering, FOS: Mechanical engineering, External quantum efficiency (EQE), FOS: Medical engineering, Quantum efficiency, Passivation, Layer (electronics), Engineering, Plasmonics for Photovoltaic Devices, FOS: Electrical engineering, electronic engineering, information engineering, Anti-reflection coating (ARC), Electrical and Electronic Engineering, Nanowire Nanosensors for Biomedical and Energy Applications, Optoelectronics, Photovoltaic system, Silicon solar cell, Reflection (computer programming), Physics, Solar cell, Computer science, Materials science, Mechanical engineering, Programming language, Silicon Solar Cell Technology, Arc (geometry), Electrical engineering, Physical Sciences, Energy conversion efficiency, Crystalline silicon
Silicon nitride, Composite material, Surface passivation, Silicon, Surface Recombination, QC1-999, Biomedical Engineering, FOS: Mechanical engineering, External quantum efficiency (EQE), FOS: Medical engineering, Quantum efficiency, Passivation, Layer (electronics), Engineering, Plasmonics for Photovoltaic Devices, FOS: Electrical engineering, electronic engineering, information engineering, Anti-reflection coating (ARC), Electrical and Electronic Engineering, Nanowire Nanosensors for Biomedical and Energy Applications, Optoelectronics, Photovoltaic system, Silicon solar cell, Reflection (computer programming), Physics, Solar cell, Computer science, Materials science, Mechanical engineering, Programming language, Silicon Solar Cell Technology, Arc (geometry), Electrical engineering, Physical Sciences, Energy conversion efficiency, Crystalline silicon
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