Spiro-TTB

$1,000.00

* The information on this page is a summary and is not intended to cover all available information about this medication. It does not cover all possible uses, directions, precautions, drug interactions or adverse effects and is not a substitute for the expertise and judgement of your healthcare professional.

Compound Description

Spiro-TTB: Advancing the Field of Organic Light-Emitting Devices

The organic electronics sector is witnessing rapid advancements and Spiro-TTB is at the forefront of these innovations. Recognized for its electron-rich structure and versatility, Spiro-TTB is making significant strides in the development of OLED devices, perovskite solar cells and other organic photovoltaic devices.

Understanding Spiro-TTB

Spiro-TTB, scientifically known as 2,2′,7,7′-Tetra(N,N-di-p-tolyl)amino-9,9-spirobifluorene, is derived from a core of spirobifluorene with di-p-tolylamines attached at the 2- and 7-positions. This unique molecular configuration imparts an electron-rich nature to the compound, making it an ideal candidate for various optoelectronic applications.

Key Features of Spiro-TTB

  • Hole Transport Layer (HTL) Material: Spiro-TTB’s electron-rich structure makes it a prime choice for use as a hole transport layer in OLED devices. Its ability to effectively transport holes ensures optimal device performance.
  • Electron Blocking Layer (EBL) Material: Its properties also allow it to serve as an electron blocking layer, preventing unwanted electron movement and enhancing device efficiency.
  • Host Material in PhOLEDs: Spiro-TTB is extensively used in phosphorescent organic light-emitting diodes (PhOLEDs) as a host material, facilitating better light emission and device longevity.
  • Compatibility with Perovskite Solar Cells and OPVs: Beyond OLEDs, Spiro-TTB finds applications in perovskite solar cells and organic photovoltaic devices, underscoring its versatility in the organic electronics domain.

Spiro-TTB in Organic Electronics

Spiro-TTB’s prominence in the organic electronics sector is not just due to its molecular structure but also its adaptability. When compared to other compounds like Spiro-OMeTAD, Spiro-TTB showcases a deeper HOMO energy level, which can potentially lead to enhanced device performance. Its ability to form exciplexes with other materials further broadens its application scope, making it a valuable asset in the research and development of next-generation organic electronic devices.

Conclusion

Spiro-TTB is shaping the future of organic electronics with its multifaceted applications and unique molecular attributes. As research continues to delve deeper into its potential, Spiro-TTB is poised to set new benchmarks in the OLED and organic photovoltaic sectors.

Frequently asked questions

How does my subscription work?

A seemingly elegant design can quickly begin to bloat with unexpected content or break under the weight of actual activity. Fake data can ensure a nice looking layout but it doesn’t reflect what a living, breathing application must endure. Real data does.

How do I edit what's in my plan?

A seemingly elegant design can quickly begin to bloat with unexpected content or break under the weight of actual activity. Fake data can ensure a nice looking layout but it doesn’t reflect what a living, breathing application must endure. Real data does.

Can I change my next delivery date?

A seemingly elegant design can quickly begin to bloat with unexpected content or break under the weight of actual activity. Fake data can ensure a nice looking layout but it doesn’t reflect what a living, breathing application must endure. Real data does.

It's been a while since I took the quiz. Can I get a new recommendation?

A seemingly elegant design can quickly begin to bloat with unexpected content or break under the weight of actual activity. Fake data can ensure a nice looking layout but it doesn’t reflect what a living, breathing application must endure. Real data does.

Still stumped? Contact us