Share To

Article Url


Manuscript ID : JOPN-2211-1273 (R2) Visit : 51 Page: 37 - 52

10.30495/jopn.2024.31254.1273

Article Type: Original Research

Subject Areas : Journal of Optoelectronical Nanostructures

Maryam Amirhoseiny 1 , Majid Zandi 2 , Ahad Kheiri 3

1 - Department of Engineering Sciences and Physics, Buein Zahra Technical University, Buein Zahra, Qazvin, Iran
2 - Shahid Beheshti University, Tehran, Iran
3 - Shahid Beheshti University, Tehran, Iran

Received: 2022-11-20 Accepted : 2023-12-06 Published : 2024-02-01

Keywords:

Abstract :

References:


  1.  Alahyarizadeh, G., et al. Performance of deep violet InGaN double quantum wells laser diodes with quaternary superlattice barriers structure, Journal of Renewable Energy and Environment. 9(1) (2022) 106-111. Available: https://doi.org/10.30501/jree.2021.300112.1246
    2.
  2.  Amirhoseiny, M., et al. Enhancement of deep violet InGaN double quantum wells laser diodes performance characteristics using superlattice last quantum barrier. Journal of Optoelectronical Nanostructures. 6(2) (2021) 107-120. Available: https://doi.org/10.30495/jopn.2021.4776
    3.
  3.  Yahyazadeh, Rajab, and Zahra Hashempour. Non-radiative Auger Current in a InGaN/GaN Multiple Quantum Well Laser Diode under Hydrostatic Pressure and Temperature. Journal of Optoelectronical Nanostructures 8(2) (2023) 81-107. Available: 10.30495/JOPN.2023.31803.1289
    4.
  4.  Alahyarizadeh, G and Amirhoseiny, M. Performance characteristics of deep violet InGaN DQW lasers based on different compliance layers. Optik, 131 (2017), 194-200. Available: https://doi.org/10.1016/j.ijleo.2016.11.093
    5.
  5.  Singh, K.J., et al., Numerical simulation model of compositionally graded optimized radiation hard InGaN multi-junction space solar cell. Presented at SEISCON 2011. [online]. Available: https://doi.org/10.1049/cp.2011.0453
    6.
  6.  Alahyarizadeh, G., et al. Effect of different EBL structures on deep violet InGaN laser diodes performance. Optics & Laser Technology, 76 (2016) 106-112. Available: https://doi.org/10.1016/j.optlastec.2015.08.007
    7.
  7.  Alahyarizadeh, G., et al.  Performance enhancement of deep violet InGaN double quantum wells laser diodes with quaternary superlattice barriers structure. Journal of Renewable Energy and Environment, 9(1) (2022). 106-111. Available:  https://doi.org/10.30501/jree.2021.300112.1246
    8.
  8.  Amirhoseiny, M., et al. Effect of annealing temperature on IR-detectors based on InN nanostructures. Vacuum, 106 (2014). 46-48. Available: https://doi.org/10.1016/j.vacuum.2014.03.010
    9.
  9.  Al-Ezzi, et al, Photovoltaic Solar Cells: A Review. Applied System Innovation. 5(4), (2022) 67. Available: https://doi.org/10.3390/asi5040067
    10.
  10.  Xu, Tao, and Luping Yu. How to design low bandgap polymers for highly efficient organic solar cells. Materials today 17(1) (2014) 11-15. Available: https://doi.org/10.1016/j.mattod.2013.12.005
    11.
  11.  Yahyazadeh, R., & Hashempour, Z. Effect of Hydrostatic Pressure on Optical Absorption Coefficient of InGaN/GaN of Multiple Quantum Well Solar Cells. Journal of Optoelectronical Nanostructures, 6(2) (2021). 1-22. Available: 10.30495/JOPN.2021.27941.1221 
    12.
  12.  Verma, Manish, Soumya R. Routray, and Guru Prasad Mishra. "Analysis and optimization of BSF layer for highly efficient GaInP single junction solar cell." Materials Today: Proceedings 43 (2021) 3420-3423. Available: https://doi.org/10.1016/j.matpr.2020.09.073
    13.
  13.  Fotis, Konstantinos. Modeling and simulation of a dual-junction CIGS solar cell using Silvaco ATLAS. Diss. Monterey, California. Naval Postgraduate School, 2012.
    14.
  14.  Bouanani, B., et al. Band gap and thickness optimization for improvement of CIGS/CIGS tandem solar cells using Silvaco software. Optik 204 (2020)164217. Available: https://doi.org/10.1016/j.ijleo.2020.164217
    15.
  15.  Sefidgar, Yagub, Hassan Rasooli Saghai, and Hamed Ghatei Khiabani Azar. "Enhancing Efficiency of Two-bond Solar Cells Based on GaAs/InGaP. Journal of Optoelectronical Nanostructures 4(2) (2019) 83-102. Available: 20.1001.1.24237361.2019.4.2.7.7
    16.
  16.  Galiana, B., et al., A comparative study of BSF layers for GaAs-based single-junction or multijunction concentrator solar cells. Semiconductor science and technology. 21(10) (2006)1387. Available: https://doi.org/10.1088/0268-1242/21/10/003
    17.
  17.  Huang, Xuanqi. Design and development of high performance III-nitrides photovoltaics. Diss. Arizona State University, 2020.
    18.
  18.  Raman, Ashish, Chetan Chaturvedi, and Naveen Kumar. Multi‐Quantum Well‐Based Solar Cell. Electrical and Electronic Devices, Circuits, and Materials: Technological Challenges and Solutions (2021) 351-372. Available: https://doi.org/10.1002/9781119755104.ch19
    19.
  19.  Madani, Homa Hashemi, Mohammad Reza Shayesteh, and Mohammad Reza. A Carbon Nanotube (CNT)-based SiGe Thin Film Solar Cell Structure. Journal of Optoelectronical Nanostructures. 6(1) (2021) 71-86. Available: 10.30495/JOPN.2021.4541
    20.
  20.  Emery, K., Photovoltaic efficiency measurements. In Organic Photovoltaics V. 5520 (2004) 36-44. SPIE. Available: https://doi.org/10.1117/12.562712
    21.
  21.  Hashemi Nassab, Sayed Mohammad Sadegh, Mohsen Imanieh, and Abbas Kamaly. The Effect of Doping and the Thickness of the Layers on CIGS Solar Cell Efficiency. Journal of Optoelectronical Nanostructures 1(1) (2016) 9-24. Available: 20.1001.1.24237361.2016.1.1.2.9
    22.
  22.  Jacob, N., et al., Numerical device modeling for direct Z-scheme junctions using a solar cell simulator. Solar Energy, 259 (2023). 320-327. Available: https://doi.org/10.1016/j.solener.2023.05.013
    23.
  23.  Häberlin, H. Photovoltaics: system design and practice. John Wiley & Sons (2012).
    24.
  24.  Zhao, Y., et al. Toward high efficiency at high temperatures: Recent progress and prospects on InGaN-based solar cells. Materials Today Energy, 31 (2023), 101229. Available: https://doi.org/10.1016/j.mtener.2022.101229
    25.
  25.  Sarollahi, M., et al., Study of simulations of double graded InGaN solar cell structures. Journal of Vacuum Science & Technology B, 40(4) (2022).042203. Available: https://doi.org/10.1116/6.0001841
    26.
  26.  Shan, H., et al. Degradation in Efficiency of InGaN/GaN Multiquantum Well Solar Cells With Rising Temperature. IEEE Transactions on Electron Devices, 69(11) (2022). 6195-6200. Available:   https://doi.org/10.1116/6.0001841 
    27.
  27.  Chen, K.-F., C.-L. Hung, and Y.-L. Tsai, Simulation study of InGaN intermediate-band solar cells. Journal of Physics D: Applied Physics. 49(48) (2016) 485102. Available: http://dx.doi.org/10.1109/TED.2017.2755069
    28.
  28.  Al-Ezzi, A. S., & Ansari, M. N. M. Photovoltaic solar cells: a review. Applied System Innovation, 5(4) (2022), 67. Available: https://doi.org/10.3390/asi5040067
    29.
  29.  Sabbah, H., Numerical Simulation of 30% Efficient Lead-Free Perovskite CsSnGeI3-Based Solar Cells. Materials (Basel). 15(9) (2022) 3229. Available: https://doi.org/10.3390%2Fma15093229
    30.
  30.  Law, D.C., et al., Future technology pathways of terrestrial III–V multijunction solar cells for concentrator photovoltaic systems. Solar Energy Materials and Solar Cells. 94(8) (2010) 1314-1318. Available: https://doi.org/10.1016/j.solmat.2008.07.014
    31.

Sanad

Sanad is a platform for managing Azad University publications

Links

Related Centers

Technical Support

Official pages

The rights to this website are owned by the Raimag Press Management System.
Copyright © 2021-2024

Home| Login| About Us| Contact Us|
[فارسی] [العربية] [fa] [ar]