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1,3-bis[3,5-di(pyridin-3-yl)phenyl]benzene, commonly referred to as PBDB, is a promising molecule with a wide range of applications in the chemical industry.
Its unique structure, consisting of a rigid benzene ring with two pyridine groups attached to it, provides PBDB with several advantageous properties.
One of the most notable applications of PBDB is in the field of electronics.
Its high electronic conductivity and excellent thermal stability make it an ideal material for use in organic thin-film transistors, light-emitting diodes, and solar cells.
In addition, PBDB can be used in organic light-emitting diodes (OLEDs) as a hole transport material, due to its high hole mobility.
Another application of PBDB is in the field of catalysis.
PBDB has been found to be an efficient catalyst for the hydrogenation of various organic compounds.
The unique structure of PBDB allows it to bind to the substrate in a bidentate manner, making it a more effective catalyst for the hydrogenation reaction.
PBDB also has applications in the field of organic electrochemistry.
It has been shown to be an efficient electrochemical material for redox reactions, owing to its ability to undergo facile electron transfer.
This makes it a promising material for the development of bioanalytical sensors and biosensors.
In addition, PBDB is also being explored for its potential in the field of photovoltaics.
Its high Electronic Conductivity and good thermal stability make it a promising material for use in solar cells.
It is also used as a sensitizer in dye-sensitized solar cells (DSSCs) due to its ability to absorb light in the visible region and transfer the energy to the sensitizer.
Another promising application of PBDB is in the field of pharmaceuticals.
PBDB has been found to have antimicrobial properties and it can be used as a potential drug candidate.
The antimicrobial activity of PBDB can be attributed to its ability to interact with the bacterial membrane leading to leakage of cellular contents and eventual death of the bacterium.
PBDB also has applications in the field of supercapacitors and energy storage.
PBDB shows good capacitive performance and good thermal stability.
These properties make it an ideal material for use in supercapacitors and other energy storage devices.
Finally, PBDB is also being explored for its potential in the field of gas sensing.
Its ability to undergo facile electron transfer and its sensitivity to various gases make it a promising material for use in gas sensors.
In conclusion, PBDB is a versatile molecule with a wide range of applications in the chemical industry.
Its unique structure and properties make it an ideal material for use in electronics, catalysis, organic electrochemistry, photovoltaics, pharmaceuticals, supercapacitors, energy storage, and gas sensors.
Owing to its excellent properties, PBDB is likely to have a significant impact in the development of various chemical technologies in the near future.
