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2-(3-BroMophenyl)-9H-BroMophenylcarbazole, also known as BTBBC, is a new and promising material in the field of organic electronics and photovoltaics.
In recent years, it has been studied extensively due to its unique properties, including high hole mobility, good thermal stability, and high photovoltaic performance.
One of the most notable applications of BTBBC is in the field of organic photovoltaics.
Organic photovoltaics is a type of solar cell technology that utilizes organic materials, such as BTBBC, to convert sunlight into electricity.
BTBBC is used as a material for the photovoltaic cell's active layer, where it absorbs light and generates electricity.
BTBBC-based photovoltaic cells have shown promising results in terms of power conversion efficiency (PCE).
PCE is a measure of how efficiently a photovoltaic cell can convert sunlight into electricity.
BTBBC-based photovoltaic cells have achieved PCEs of up to 14%, which is comparable to traditional inorganic solar cells.
In addition to its use in photovoltaics, BTBBC has also been studied for its application in organic light-emitting diodes (OLEDs).
OLEDs are a type of lighting technology that utilizes organic materials to generate light.
BTBBC has been used as a material for the emissive layer in OLEDs, where it emits light when excited by an electric current.
BTBBC-based OLEDs have shown promising results in terms of efficiency and stability.
They have achieved efficiencies of up to 27%, which is higher than many other organic emitters.
They also have good thermal stability, which is important for their use in high-power applications.
Another potential application of BTBBC is in the field of sensors.
BTBBC has been studied for its ability to detect various gases and molecules, including CO2, NO2, and H2S.
This makes it a promising material for use in gas sensors, which can be used in a variety of applications, including environmental monitoring, safety, and security.
BTBBC-based gas sensors have shown good sensitivity and selectivity for different gases.
For example, one study reported a sensitivity of 31.
5 ppb for CO2 and a selectivity of 554 for CO2 over NO2.
BTBBC is also a promising material for use in transistors and other electronic devices.
It has been studied for its ability to form stable and efficient p-n junctions, which are important for the operation of many electronic devices.
BTBBC has been used as a material for the p-type semiconductor in p-n junction devices, where it has shown good stability and high hole mobility.
In conclusion, BTBBC is a promising material with a wide range of potential applications in the chemical industry.
Its unique properties, including high hole mobility, good thermal stability, and high photovoltaic performance, make it a valuable material for use in organic photovoltaics, OLEDs, gas sensors, and other electronic devices.
As research on BTBBC continues, it is likely that its applications will continue to grow and evolve, contributing to the advancement of organic electronics and photovoltaics.
![9-[1,1'-biphenyl]-4-yl-3,3'-Bi-9H-carbazole](https://file.echemi.com/fileManage/upload/category/ac71ac0d-8ef6-11ec-89e5-fa163ed06441.png)
