Unlock Advanced Organic Electronics with [2,2'-Bithiophen]-5-yltrimethyl-stannane
High-purity organotin compound essential for cutting-edge OLED, OFET, and OPV material development.
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[2,2'-Bithiophen]-5-yltrimethyl-stannane
This high-purity compound, identified by CAS 133144-35-1, is a critical intermediate for synthesizing advanced materials used in organic electronic devices. Its specific chemical structure and high purity level of 97% min. make it ideal for researchers and manufacturers seeking reliable building blocks for next-generation technologies.
- Discover the utility of 2,2'-bithiophen-5-yltrimethyl-stannane cas 133144-35-1 in creating next-generation organic light-emitting diodes, field-effect transistors, and organic photovoltaics.
- Explore the applications of OLED OFET OPV materials that utilize high-purity organotin compounds, ensuring superior device performance and longevity.
- Learn about trimethyl-stannane for organic electronics and its crucial role in facilitating complex molecular syntheses for semiconductor applications.
- Investigate the benefits of high purity organotin compounds in achieving consistent and reliable results in advanced material fabrication processes.
Advantages
Enhanced Device Performance
Utilizing this bithiophene derivative for OFETs as a key component allows for improved charge carrier mobility and enhanced device performance in organic field-effect transistors.
Material Purity Assurance
With a guaranteed minimum purity of 97%, our high purity organotin compounds ensure reproducible synthesis and optimal material properties for your demanding applications.
Versatile Synthesis
The reactive trimethyl-stannane group facilitates versatile coupling reactions, making it an indispensable tool for creating complex molecular architectures in OLED material synthesis.
Key Applications
OLED Materials
Enhance luminescence efficiency and device stability in OLED displays and lighting by incorporating our advanced OLED materials synthesized using this key intermediate.
OFET Materials
Achieve higher charge carrier mobility and faster switching speeds in organic field-effect transistors by leveraging the properties of OFET materials derived from this compound.
OPV Materials
Improve power conversion efficiency in organic photovoltaic cells with novel OPV materials that benefit from the unique electronic characteristics of bithiophene derivatives.
Organic Semiconductors
Serve as a crucial building block in the development of new organic semiconductors, enabling the creation of flexible and low-cost electronic devices.