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Main Authors: Abir, Ahnaf Tahmid, Joy, Arifuzzaman, Hossain, Jaker
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.01707
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author Abir, Ahnaf Tahmid
Joy, Arifuzzaman
Hossain, Jaker
author_facet Abir, Ahnaf Tahmid
Joy, Arifuzzaman
Hossain, Jaker
contents In this work, Machine Learning (ML) techniques have been employed to explore the highest performing single-heteronunction thermophotovoltaic cell. Initially, traditional homo junction TPV cells have been explored using ML methodologies for the optimal material combinations. ML methods have notably been devoted to analyze the importance of each parameter in the model, thereby improving the comprehension of the system's behavior and facilitating design optimization. Following this investigation, it has been found that Ge emerged as the most effective emitter layer when paired with the optimal base layer, InGaAsSb compound that possesses a direct bandgap of 0.53 eV. Subsequently, a p-Ge/n-InGaAsSb single-heterojunction TPV cell is introduced executing a device transport model featuring a p-n structure. This cell operated at black body (TBB) and cell temperatures of 1578 K and 300 K, respectively. Through meticulous optimization efforts, the performance of the TPV cell is significantly enhanced resulting in an impressive efficiency of 16.50%. This efficiency is accompanied by a short circuit current, JSC=15.53 A/cm2, an open-circuit voltage, VOC=0.47 V, and a fill factor FF=79.5%. These findings suggest that this structural configuration holds considerable promise for the development of high-performance TPV cells.
format Preprint
id arxiv_https___arxiv_org_abs_2408_01707
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Machine Learning Assisted Revelation of the Best Performing Single Hetero-junction Thermophotovoltaic Cell
Abir, Ahnaf Tahmid
Joy, Arifuzzaman
Hossain, Jaker
Applied Physics
In this work, Machine Learning (ML) techniques have been employed to explore the highest performing single-heteronunction thermophotovoltaic cell. Initially, traditional homo junction TPV cells have been explored using ML methodologies for the optimal material combinations. ML methods have notably been devoted to analyze the importance of each parameter in the model, thereby improving the comprehension of the system's behavior and facilitating design optimization. Following this investigation, it has been found that Ge emerged as the most effective emitter layer when paired with the optimal base layer, InGaAsSb compound that possesses a direct bandgap of 0.53 eV. Subsequently, a p-Ge/n-InGaAsSb single-heterojunction TPV cell is introduced executing a device transport model featuring a p-n structure. This cell operated at black body (TBB) and cell temperatures of 1578 K and 300 K, respectively. Through meticulous optimization efforts, the performance of the TPV cell is significantly enhanced resulting in an impressive efficiency of 16.50%. This efficiency is accompanied by a short circuit current, JSC=15.53 A/cm2, an open-circuit voltage, VOC=0.47 V, and a fill factor FF=79.5%. These findings suggest that this structural configuration holds considerable promise for the development of high-performance TPV cells.
title Machine Learning Assisted Revelation of the Best Performing Single Hetero-junction Thermophotovoltaic Cell
topic Applied Physics
url https://arxiv.org/abs/2408.01707