Optimal band gaps for InGaN single and double junction solar cells

机译：InGaN单结和双结太阳能电池的最佳带隙

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The objective of this paper is to find out the optimum band gap energy for InGaN single and double junction solar cells providing the best efficiencies. The different physical phenomena occurring in the solar cells structures were taken into account. InGaN-based single and double junction solar cells were simulated with different band gap energy taking into account the dependence of the physical, optical and electrical properties on the InGaN material composition. The InGaN solar cells structures were also optimized for each band gap. The investigation results show that the best efficiencies of the single and double junction InGaN solar cells of about 26.51 % and 34.93 %, respectively, were obtained for the optimized InGaN (1.39 eV) and InGaN/InGaN (1.73 eV/1.13 eV) structures. Furthermore, our obtained results were compared with those reported by the others published works.

机译：本文的目的是找出能提供最佳效率的InGaN单结和双结太阳能电池的最佳带隙能量。考虑了在太阳能电池结构中发生的不同物理现象。考虑到物理，光学和电学性质对InGaN材料成分的依赖关系，使用不同的带隙能量模拟了基于InGaN的单结和双结太阳能电池。还针对每个带隙对InGaN太阳能电池结构进行了优化。研究结果表明，对于优化的InGaN（1.39 eV）和InGaN / InGaN（1.73 eV / 1.13 eV）结构，单结和双结InGaN太阳能电池的最佳效率分别约为26.51％和34.93％。此外，我们将获得的结果与其他已发表作品的报告进行了比较。

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来源
《2017 International Conference on Advanced Systems and Electric Technologies》|2017年|335-339|共5页
会议地点 Hammamet(TN)
作者
A. Mesrane; A. Mahrane; F. Rahmoune; A. Oulebsir;
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作者单位

Laboratoire LIMOSE, Université M'hamed Bougara de Boumerdès, 35000 Boumerdès, Algeria;

Unité de Développement des Equipements Solaires(UDES), Centre de Développement des Energies, Renouvelables (CDER), Route Nle No. 11, BP 386, Bou Ismaïl, 42415 Tipaza, Algeria;

Laboratoire LIMOSE, Université M'hamed Bougara de Boumerdès, 35000 Boumerdès, Algeria;

Laboratoire d'Electronique Quantique, Faculté de Physique, USTHB, El Alia BP 32, Bab Ezzouar, 16111, Alger, Algeria;

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正文语种 eng
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关键词
Photovoltaic cells; Photonic band gap; Junctions; Metals; Doping; Optimization;

机译：光伏电池;光子带隙;结;金属;掺杂;优化;

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专利

1. Design and Realization of Wide-Band-Gap ( 2.67 eV) InGaN p-n Junction Solar Cell [J] . Jampana B.R., Melton A.G., Jamil M., Electron Device Letters, IEEE . 2010,第1期

机译：宽带隙（2.67 eV）InGaN p-n结太阳能电池的设计与实现
2. Optimal Bandgap in a 2D Ruddlesden-Popper Perovskite Chalcogenide for Single-Junction Solar Cells [J] . Niu Shanyuan, Sarkar Debarghya, Williams Kristopher, Chemistry of Materials: A Publication of the American Chemistry Society . 2018,第15期

机译：用于单结太阳能电池的2D Ruddlesden-popper popperskite Chalogenere的最佳带隙
3. Analysis, optimisation and experimental validation of n + aSi:H/i-aSi:H/p +aSiGe:H graded band gap single junction solar cell [J] . J. Fatima Rasheed, V. Suresh Babu Results in Physics . 2020,第60期

机译：的分析，优化和实验验证 N + ASI：H / I-ASI：H / P + ASIGE：H分级带隙单结太阳能电池
4. Optimal band gaps for InGaN single and double junction solar cells [C] . A. Mesrane, A. Mahrane, F. Rahmoune, International Conference on Advanced Systems and Electric Technologies . 2017

机译：IngaN单结和双结太阳能电池的最佳带空隙
5. Development of high band gap materials for tandem solar cells and simulation studies on mechanical tandem solar cells. [D] . Vijayakumar, Vishnuvardhanan. 2013

机译：串联太阳能电池用高禁带材料的开发以及机械串联太阳能电池的仿真研究。
6. Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration [O] . Joya Zeitouny, Eugene A. Katz, Alain Dollet, -1

机译：多结太阳能电池的带隙工程：串联电阻和太阳能集中度的影响
7. Optimal Bandgap in a 2D Ruddlesden–Popper Perovskite Chalcogenide for Single-Junction Solar Cells [O] . Shanyuan Niu, Debarghya Sarkar, Kristopher Williams, 2018

机译：用于单结太阳能电池的2D Ruddlesden-popper Phalcskite Chalcogenere的最佳带隙
8. High band gap 2-6 and 3-5 tunneling junctions for silicon multijunction solar cells [R] . 1986

机译：用于硅多结太阳能电池的高带隙2-6和3-5隧道结

Optimal band gaps for InGaN single and double junction solar cells

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