B4PymPm

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* 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.

General information

Cas number	1030380-51-8
Fluorescence	λmax = 410 nm in film
Classification	Organic light-emitting diodes, Electron transport layer materials (ETL), Electron injection layer materials (EIL), Hole blocking layer materials (HBL), Emmiting layer materials (EML), Host materials,
Purity	Sublimed: >99.0% (HPLC)
Homo Lumo	N/A
Absorption	λmax = 250 nm in DCM
Chemical Formula	C37H26N6
Melting Point	374 °C
Synonyms	4,6-Bis(3,5-di-4-pyridinylphenyl)-2-methylpyrimidine
Appearance	White powder/crystals
Full Name	4,6-Bis(3,5-di(pyridin-4-yl)phenyl)-2-methylpyrimidine
Purification Techniques	Sublimed Materials
Transport Layers	Electron Injection Layer (EIL) , Electron Transport Layer (ETL) / Hole Blocking Layer (HBL)
TADF Materials	Other TADF materials
Name	B4PymPm

Compound Description

B4PymPm Specification: The Apex of OLED Advancements

The ever-expanding domain of organic light-emitting diodes (OLEDs) is propelled by a diverse array of materials and compounds. Among these, B4PymPm—fully known as 4,6-Bis(3,5-di(pyridin-4-yl)phenyl)-2-methylpyrimidine—emerges as a pivotal element in the OLED technology stack.

Understanding B4PymPm

B4PymPm is a heterocyclic organic compound distinguished by its unique molecular structure. B4PymPm is a structural isomer of B2PymPm and B3PymPm and it features a central 2-methylpyrimidine core and is adorned with four pyridine appendages. This compound holds particular significance in the field of organic electronic devices, including OLEDs.

Key Features of B4PymPm

Electron Transport Material: Owing to its donor-acceptor configuration, B4PymPm serves as an exemplary material in electron transport layers or hole blocking layers. This ensures that OLEDs function with optimal efficiency and possess extended lifetimes.

High Thermal Stability: The compound’s elevated thermal stability and glass transition temperature render it suitable for high-performance optoelectronic devices, thereby contributing to their longevity.

Versatile Applications: Beyond its role in OLEDs, B4PymPm finds applications in various other optoelectronic devices, such as organic solar cells and field-effect transistors, further attesting to its versatility.

The Role of B4PymPm in Contemporary OLEDs

In the current landscape of OLED technology, the demand for materials that offer elevated efficiency, durability, and reduced energy consumption is incessant. B4PymPm, with its multifaceted properties, aligns seamlessly with these prerequisites. Its efficient charge transport capabilities and high thermal stability ensure not only optimal functionality but also an extended lifespan for OLEDs.

Conclusion

The OLED sector is in a constant state of evolution, driven by the imperative for materials that are both efficient and durable. B4PymPm, endowed with a unique set of properties and functionalities, is poised to play a substantial role in shaping the future of OLED technology. As research advances and technology matures, B4PymPm is anticipated to find an expanding array of applications in organic electronic devices.

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