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Merck

698687

Sigma-Aldrich

聚[(9,9-二辛基芴基-2,7-二基)-alt-(苯并[2,1,3]噻二唑-4,8-二基)]

average Mn ≤25000

别名:

F8BT, 聚(9,9-二辛基- alt -苯并噻二唑)

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About This Item

线性分子式:
(C35H42N2S)n
分類程式碼代碼:
12352103
NACRES:
NA.23

形狀

powder

品質等級

分子量

average Mn ≤25000

溶解度

THF: soluble
chloroform: soluble

螢光

λex 447 nm; λem 530-560 nm in chloroform

Mw/Mn

<3

半導體屬性

P-type (mobility=4×10−3 cm2/V·s)

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一般說明

F8BT是芴共聚物,用作发光聚合物(LEP),具有最低未占分子轨道(LUMO)能量低、电子迁移率高和亮度高的特点。

應用

F8BT可与聚(9,9-二-正-辛基芴基-2,7-二基)(PTO)同时使用,通过评估电导率和噪声源密度(Nt)绘制噪声源对光导电荷传输的影响。 还可与单壁碳纳米管(SWCNT)形成纳米复合材料,材料具有优异电性能和高塞贝克(Seebeck)系数,在开发光伏发电和生物质能领域具有应用潜力。可以通过在 FEDOT:PSS 膜上沉积 F8 和 F8BT 的混合物,制造有机发光二极管(OLED)器件。

儲存類別代碼

11 - Combustible Solids

水污染物質分類(WGK)

WGK 3

閃點(°F)

Not applicable

閃點(°C)

Not applicable

個人防護裝備

Eyeshields, Gloves, type N95 (US)


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分析证书(COA)

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Surface, interface and electronic properties of F8: F8BT polymeric thin films used for organic light-emitting diode applications
Borges BG, et al.
Polymer International, 67(6), 691-699 (2018)
Mapping nanoscale effects of localized noise-source activities on photoconductive charge transports in polymer-blend films
Shekhar S, et al.
Nanotechnology, 29(20), 205204-205204 (2018)
Surface chemistry of photoluminescent F8BT conjugated polymer nanoparticles determines protein corona formation and internalization by phagocytic cells
Ahmad Khanbeigi R, et al.
Biomacromolecules, 16(3), 733-742 (2015)
Morphology-dependent trap formation in bulk heterojunction photodiodes
Shao G, et al.
The Journal of Physical Chemistry B, 117(16), 4654-4660 (2013)
Enhanced figure of merit of poly (9, 9-di-n-octylfluorene-alt-benzothiadiazole) and SWCNT thermoelectric composites by doping with FeCl3
Zhou X, et al.
Journal of Applied Polymer Science, 16(3), 47011-47011 (2018)

商品

The development of high-performance conjugated organic molecules and polymers has received widespread attention in industrial and academic research.

Since their discovery, organic light emitting devices (OLEDs) have evolved from a scientific curiosity into a technology with applications in flat panel displays and the potential to revolutionize the lighting market. During their relatively short history, the technology has rapidly advanced, and device efficiencies have increased more than 20-fold, approaching the theoretical limit for internal quantum efficiencies.

Organic photovoltaics (OPVs) represent a low-cost, lightweight, and scalable alternative to conventional solar cells. While significant progress has been made in the development of conventional bulk heterojunction cells, new approaches are required to achieve the performance and stability necessary to enable commercially successful OPVs.

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