The Bridge - Issue 2, 2021 - 26

Feature
Modeling organic semiconductor metallic contact and optoelectronic
parameters with reference to inorganic semiconductors
REFERENCES
[1] Zhu,Y. B. and Ang,L. K. , " Analytical re-derivation of space
charge limited current in solids using capacitor model " , Journal of
Applied Physics, vol. 110, pp. 094514, Oct. 2011.
[2] Ishii, H., Hayashi, N., Ito, E., Washizu, Y., Sugi, K., Kimura, Y.,
Niwano, M., Ouchi, O. and Seki, K., " Kelvin Probe Study of Band
Bending at Organic Semiconductor/Metal Interfaces: Examination
of Fermi Level Alignment " , phys. stat. sol. (a), vol. 201, pp. 10751094,
May 2004.
[3] Mikhnenko, Oleksandr V. and Blom, Paul W. M. and Nguyen,
Thuc-Quyen, " Exciton diffusion in organic semiconductors " , Energy
Environ. Sci., vol. 8, pp. 1867-1888, May 2015.
[4] Eftaiha, Ala'a F. and Sun, Jon-Paul and Hill, Ian G. and Welch,
Gregory C., " Recent advances of non-fullerene small molecular
acceptors for solution processed bulk heterojunction solar cells " , J.
Mater. Chem. A, vol. 2, pp. 1201- 1213, Oct. 2014.
[5] Jun Yuan, Yunqiang Zhang, Liuyang Zhou, Guichuan Zhang,
Hin-Lap Yip, Tsz-Ki Lau, Xinhui Lu, Can Zhu, Hongjian Peng, Paul
A. Johnson, Mario Leclerc, Yong Cao, Jacek Ulanski, Yongfang Li,
Yingping Zou, " Single-Junction Organic Solar Cell with over 15%
Efficiency Using Fused-Ring Acceptor with Electron-Deficient Core " ,
Joule, Vol. 3, pp. 1140-1151,April 2019.
[6] Petr P. Khlyabich, Beate Burkhart, Andrey E. Rudenko, Barry C.
Thompson, " Optimization and simplification of polymer-fullerene
solar cells through polymer and active layer design " , Polymer, Vol.
54, pp. 5267-5298, Sept. 2013.
[7] Si Chen, " Dielectric constant measurement of P3HT,
polystyrene, and polyethylene " , Master's Thesis / Essay, Chemistry,
2017.
[8] W. Abdelaziz, A. Zekry, A. Shaker,M. Abouelatta, Numerical
study of organic graded bulk heterojunction solar cell using SCAPS
simulation, solar energy, Vol. 211, pp. 375-382, Nov. 2020.
[9] Xi Liu, Boming Xie, Chunhui Duan, Zhaojing Wang, Baobing
Fan, Kai Zhang, Baojun Lin, J. Fallon, M. Colberts, Wei Ma, A. Rene,
J. Janssen, Fei Huang, Yong Cao, A high dielectric constant nonfullerene
acceptor for efficient bulk-heterojunction organic solar
cells, J. Mater. Chem., Vol. 6, pp. 395-403, 2018.
[10] Wang, Pang and Wang, Hui and Jeong, Mingyu and Lee, Sang
Myeon and Du, Baocai and Mao, Yuchao and Ye, Fanghao and
Zhang, Huijun and Li, Donghui and Liu, Dan and Yang, Changduk
and Wang, Tao, " Dopant-free polymeric hole transport materials
for efficient CsPbI2Br perovskite cells with a fill factor exceeding
84% " , J. Mater. Chem. C, vol. 8, pp. 8507-8514, 2020.
[11] Kan, Bin and Zhang, Jiangbin and Liu, Feng and Wan,
Xiangjian and Li, Chenxi and Ke, Xin and Wang, Yunchuang and
Feng, Huanran and Zhang, Yamin and Long, Guankui and Friend,
Richard H. and Bakulin, Artem A. and Chen, Yongsheng, " FineTuning
the Energy Levels of a Nonfullerene Small-Molecule
Acceptor to Achieve a High Short-Circuit Current and a Power
Conversion Efficiency over 12\% in Organic Solar Cells " , Advanced
Materials, Vol. 30, PP. 1704904, Dec. 2017.
[12] Lee, E.J.; Choi, M.H., Moon, D.K., " Enhanced Photovoltaic
Properties of Bulk Heterojunction Organic Photovoltaic Devices by
an Addition of a Low Band Gap Conjugated Polymer " , Materials,
Vol. 9, PP. 996, Nov. 2016.
[13] Elizabeth von Hauff, Vladimir Dyakonov, J├╝rgen Parisi, " Study
of field effect mobility in PCBM films and P3HT:PCBM blends " ,
Solar Energy Materials and Solar Cells, Vol. 87, pp. 149-156, May
2005.
[14] hia-Chih Chang, Jhih-Hao Tao, Che-En Tsai, Yen-Ju Cheng,
and Chain-Shu Hsu, " Cross-linked Triarylamine-Based HoleTransporting
Layer for Solution-Processed PEDOT:PSS-Free
Inverted Perovskite Solar Cells " , ACS Applied Materials &
Interfaces, Vol. 25, pp. 21466-21471, 2018.
[15] Yao, J., Qiu, B., Zhang, ZG. et al., " Cathode engineering with
perylene-diimide interlayer enabling over 17% efficiency singlejunction
organic solar cells " , Nat Commun. , Vol. 11, pp. 2726,
June 2020.
[16] Chen, Youchun and Wang, Shan and Xue, Lingwei and
Zhang, Zhiguo and Li, Haolong and Wu, Lixin and Wang, Yue and
Li, Fenghong and Zhang, Fengling and Li, Yongfang, " Insights into
the working mechanism of cathode interlayers in polymer solar
cells via [(C8H17)4N]4[SiW12O40] " , J. Mater. Chem. A, Vol. 4, pp.
19189-19196, 2016.
[17] Liu, Xiang and Chen, Zhiming and Xu, Rongguo and Zhang,
Ruiwen and Hu, Zhicheng and Huang, Fei and Cao, Yong, 'Finely
Tuned Composition in Conjugated Polyelectrolytes for Interfacial
Engineering of Efficient Polymer Solar Cells " , Small Methods, Vol.
2, pp. 1700407, March 2018.
[18] W. Abdelaziz, A. Shaker, M. Abouelatta, A. Zekry, " Possible
efficiency boosting of non-fullerene acceptor solar cell using
device simulation " , Optical Materials, Vol. 91, pp. 239-245, 2019.
[19] Zekry, A., Shaker, A., Salem, M., 2048. Chapter 1 - solar
cells and arrays: principles, analysis, and design, Advances in
Renewable Energies and Power Technologies, first ed., Yahyaoui.
Abdelhalim Zekry is a professor of
electronics at Faculty of Engineering,
Ain Shams University, Egypt. He
has worked as a staff member at
several universities. He has published
more than 300 papers. He also has
supervised more than 110 Master's
theses and 40 Doctoral Dissertations.
Prof. Zekry focuses his research
programs on the field of microelectronics and electronic
applications including communications and photovoltaics.
He has been awarded several prizes for his outstanding
research and teaching performance.
Walaa Abdelaziz is a teaching
assistant at the Modern Academy,
Egypt. She graduated from Ain
Shames University in 2005 and
earned her Master's degree in 2012
from Cairo University. She focuses
her research on renewable energy,
especially solar cells.
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The Bridge - Issue 2, 2021

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The Bridge - Issue 2, 2021 - Cover1
The Bridge - Issue 2, 2021 - Cover2
The Bridge - Issue 2, 2021 - Contents
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The Bridge - Issue 2, 2021 - Cover3
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