Large-area organic solar cells

被引：0

作者：

Min Li ^{[1
]}

Jilin Wang ^{[2
]}

Liming Ding ^{[3
]}

Xiaoyan Du ^{[1
]}

机构：

[1] School of Physics, Shandong University

[2] School of Materials Science and Engineering, Key Laboratory of New Processing Technology for Nonferrous Metals and Materials (MoE),Guilin University of Technology

[3] Center for Excellence in Nanoscience (CAS), Key Laboratory of Nanosystem and Hierarchical Fabrication (CAS), National Center for Nanoscience and Technology

来源：

Journal of Semiconductors | 2022年 / 06期

基金：

中国国家自然科学基金;

关键词：

D O I：

暂无

中图分类号：

TM914.4 [太阳能电池];

学科分类号：

080502 ;

摘要：

Organic solar cells(OSCs) have made significant progress due to the fast advances in nonfullerene acceptors(NFAs) since 2015. The power conversion efficiency(PCE)for small-area single-junction OSCs is around 19% with an active area <0.1 cm. Scalability is a key factor in developing this technology. When scaling lab cells to large-area modules, the device performance might drop. Brabec et al. proposed a stage–gate process for OSCs from R&D effort to commercialization, which includes materials development,

引用

页码：4 / 8

页数：5

共 50 条

[41] FABRICATION OF LARGE-AREA SILICON NANOWIRE ARRAYS FOR SOLAR CELLS
Lai, Wuxing
Xu, Guoqiang
Zhang, Wei
Shi, Tielin
[J]. INTERNATIONAL JOURNAL OF NANOSCIENCE, 2012, 11 (06)
[42] Nanopillars on Unpolished Substrates and Their Application in Large-Area Solar Cells
Liu, Jing
Zhang, Xinshuai
Sun, Gangjie
Wang, Yuting
Wang, Bo
Zhang, Tianchong
Yi, Futing
[J]. JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY, 2017, 17 (03) : 2012 - 2018
[43] Power Recycling of Large-Area OLEDs Using Solar Cells
Park, Jongwoon
Lee, Jongho
Shin, Dongchan
[J]. JOURNAL OF DISPLAY TECHNOLOGY, 2010, 6 (07): : 247 - 251
[44] DEVELOPMENTAL EXPERIMENTS ON LARGE-AREA SILICON SOLAR-CELLS
SILARD, AP
NANI, G
[J]. JOURNAL OF APPLIED PHYSICS, 1989, 65 (09) : 3680 - 3686
[45] LARGE-AREA, CONCENTRATOR BURIED CONTACT SOLAR-CELLS
ZHANG, FZ
WENHAM, S
GREEN, MA
[J]. IEEE TRANSACTIONS ON ELECTRON DEVICES, 1995, 42 (01) : 144 - 149
[46] Efficient large-area polymer solar cells on flexible substrates
Al-Ibrahim, M
Roth, HK
Sensfuss, S
[J]. APPLIED PHYSICS LETTERS, 2004, 85 (09) : 1481 - 1483
[47] Production technology of large-area multicrystalline silicon solar cells
Fujii, S
Fukawa, Y
Takahashi, H
Inomata, Y
Okada, K
Fukui, K
Shirasawa, K
[J]. SOLAR ENERGY MATERIALS AND SOLAR CELLS, 2001, 65 (1-4) : 269 - 275
[48] Large Area Monolithic Organic Solar Cells
Jin, Hui
Tao, Chen
Hambsch, Mike
Pivrikas, Almantas
Velusamy, Marappan
Aljada, Muhsen
Zhang, Yuliang
Burn, Paul L.
Meredith, Paul
[J]. OPTOELECTRONIC DEVICES AND INTEGRATION IV, 2012, 8555
[49] Unraveling the electrical energy loss in silver nanowire electrodes for flexible and Large-Area organic solar cells
Ren, Hao
Chen, Wei-Shuo
Chen, Jing-De
Yang, Jin-Peng
Zhang, Ye-Fan
Hou, Hong-Yi
Tian, Shuo
Ge, Heng-Ru
Li, Yan-Qing
Tang, Jian-Xin
[J]. CHEMICAL ENGINEERING JOURNAL, 2024, 481
[50] Printable and Large-Area Organic Solar Cells Enabled by a Ternary Pseudo-Planar Heterojunction Strategy
Liu, Siqi
Chen, Dong
Hu, Xiaotian
Xing, Zhi
Wan, Ji
Zhang, Lin
Tan, Licheng
Zhou, Weihua
Chen, Yiwang
[J]. ADVANCED FUNCTIONAL MATERIALS, 2020, 30 (36)

← 1 2 3 4 5 →