PTAA
기술
PTAA. Polymer for optoelectronic applications. Hole transport material for organic light-emitting diodes (OLEDs) and Perovskites. Amorphous p-type polymer semiconductor.
Four grades are available.
Custom Mw and pdi available.
Fluoro-PTAA is also available.
Fluoro-PTAA
기술
Fluoro-PTAA. Polymer for optoelectronic applications. Hole transport material for organic light-emitting diodes (OLEDs) and Perovskites. Amorphous p-type polymer semiconductor.
The use of this polymer can significantly improve the open-circuit voltage (VOC) and the fill factor (FF) of the cells in high-performance perovskite solar cells.
Fluoro-PTAA can be coated as a substrate material used for hole transport in the manufacture of many devices such as perovskite solar cells, organic light-emitting diodes (OLED) and organic field-effect transistors.
Four grades are available.
Custom Mw and pdi available.
PTAA is also available.
PCBM – PC61BM
기술
PCBM is the common abbreviation for the fullerene derivative, [6,6] phenyl-C61-butyric acid methyl ester and is one of the most commonly used electron-accepting materials in organic photovoltaic devices.
It is commonly used in flexible plastic or electronic solar cells in conjunction with an electron donor material such as P3HT (SOL4106), PCDTBT (SOL4280) or PTB7 (SOL4700) to make high Open Circuit Voltage (Voc), high Power Conversion Efficiency (PCE) bulk heterojunction solar cells, >99.9% [6,6] isomerized.
It is a more practical choice for being an electron acceptor when compared to fullerenes due to its solubility in chlorobenzene. This allows for processable donor / acceptor solution mixtures, a necessary property for “printable” solar cells.
참고 문헌
(1) Effect of PQT-12 interface layer on the performance of PCDTBT: PCBM bulk heterojunction solar cells
Author(s): Amit Kumar, Smrity Ratan, Deepak Kumar Jarwal, Ashwini Kumar Mishra, Chandan Kumar, Abhinav Pratap Singh, Bratindranath Mukherjee and Satyabrata Jit. DOI: https://doi.org/10.1088/2053-1591/ab4708
풀러렌 C60
설명
풀러렌 및 그 유도체는 유기 광전지(OPV) 분야에서 사용됩니다.
장치의 에너지 변환 효율과 보다 안정적인 태양 전지 아키텍처의 개발이 진행되었습니다.
풀러렌은 거의 모든 고성능 장치에서 전자 수용체 역할을 합니다.
이 빠르게 발전하는 기술에서 큰 성장이 예상됩니다.
ITIC-2F
기술
ITIC-F is a non-fullerene, thermally stable electron-accepting small molecules for organic photovoltaic applications (OPV), which can replace PCBMs in various systems to reach high PCE values.
참고 문헌
1. Dispersive Non-Germinate Recombination in an Amorphous Polymer: Fullerene Blend,
Author (s): Kurpiers, J., Neher, D. Dispersive Non. NATURE – Scientific Reports 6, 26832 (2016)
2. Ultrafast zero-bias photocurrent and terahertz emission in hybrid perovskites. Commun,
Author(s): Petr A. Obraztsov, Dmitry Lyashenko, Pavel A. Chizhov, Kuniaki Konishi, Natsuki Nemoto, Makoto Kuwata-Gonokami, Eric Welch, Alexander N. Obraztsov & Alex Zakhidov. NATURE – Communications Physics 1, 14 (2018).
3. An Electron Acceptor Challenging Fullerenes for Efficient Polymer Solar Cells.,
Author(s): Yuze Lin Jiayu Wang Zhi‐Guo Zhang Huitao Bai Yongfang Li Daoben Zhu Xiaowei Zhan. First published:07 January 2015
PCDTBT
기술
PCDTBT is a low Bandgap polymer for opto-electronic applications. Can be used as an electron Donor to Acceptor materials such as PC71BM (SOL5071).
참고 문헌
1. Dispersive Non-Germinate Recombination in an Amorphous Polymer: Fullerene Blend,
Author (s): Kurpiers, J., Neher, D. Dispersive Non. NATURE – Scientific Reports 6, 26832 (2016)
2. Ultrafast zero-bias photocurrent and terahertz emission in hybrid perovskites. Commun,
Author(s): Petr A. Obraztsov, Dmitry Lyashenko, Pavel A. Chizhov, Kuniaki Konishi, Natsuki Nemoto, Makoto Kuwata-Gonokami, Eric Welch, Alexander N. Obraztsov & Alex Zakhidov. NATURE – Communications Physics 1, 14 (2018).
3. An Electron Acceptor Challenging Fullerenes for Efficient Polymer Solar Cells.,
Author(s): Yuze Lin Jiayu Wang Zhi‐Guo Zhang Huitao Bai Yongfang Li Daoben Zhu Xiaowei Zhan. First published:07 January 2015
P3HT
기술
P3HT (Poly(3-hexylthiophene-2,5-diyl)) is used as an electron Donor to acceptor materials such as PCBM (SOL5061) to make proven bench marked bulk heterojunction solar cells and organic transistors.
We offer two types with different regioregularities for a different variety of research purposes.
참고 문헌
(1) Fullerenes: Non-transition Metal Cluster For Rechargeable Magnesium Battery Cathode
Author(s): Ruigang Zhang, Fuminori Mizuno and Chen Ling *
(2) Donor‐Linked Fullerenes: Photoinduced electron transfer and its potential application
Author(s): Dr. Hiroshi Imahori Prof. Yoshiteru Sakata. First published:29 October 2004
(3) Fullerene Materials for Lithium-ion Battery Applications
Author(s): Loutfy R.O., Katagiri S. (2002). In: Ōsawa E. (eds) Perspectives of Fullerene Nanotechnology. Springer, Dordrecht (Fullerene Materials for Lithium-ion Battery Applications
(4) Prospects for Using C 60 and C 70 in Lithium Batteries
Author(s): L. Seger, L. ‐Q. Wen and J. B. Schlenoff, ECS – The Electrochemical Society
