Your cart is currently empty!
Atomfair 3-Bromo-9H-carbazole C12H8BrN
Description 3-Bromo-9H-carbazole (CAS No. 1592-95-6) is a high-purity brominated carbazole derivative with the molecular formula C12H8BrN . This heterocyclic aromatic compound is widely utilized as a key intermediate in organic synthesis, pharmaceutical research, and materials science. Its rigid planar structure and bromine substituent make it an excellent building block for constructing advanced functional materials, including OLEDs, photoconductors, and charge-transporting polymers. Available in crystalline powder form, our product undergoes rigorous QC testing (HPLC, NMR) to ensure ??98% purity, meeting the stringent demands of research and industrial applications. Proper storage under inert conditions is recommended to maintain stability.
Description
Description
3-Bromo-9H-carbazole (CAS No. 1592-95-6) is a high-purity brominated carbazole derivative with the molecular formula C12H8BrN. This heterocyclic aromatic compound is widely utilized as a key intermediate in organic synthesis, pharmaceutical research, and materials science. Its rigid planar structure and bromine substituent make it an excellent building block for constructing advanced functional materials, including OLEDs, photoconductors, and charge-transporting polymers. Available in crystalline powder form, our product undergoes rigorous QC testing (HPLC, NMR) to ensure ??98% purity, meeting the stringent demands of research and industrial applications. Proper storage under inert conditions is recommended to maintain stability.
- CAS No: 1592-95-6
- Molecular Formula: C12H8BrN
- Molecular Weight: 246.10
- Exact Mass: 244.98401
- Monoisotopic Mass: 244.98401
- IUPAC Name: 3-bromo-9H-carbazole
- SMILES: C1=CC=C2C(=C1)C3=C(N2)C=CC(=C3)Br
- Synonyms: 3-bromo-9H-carbazole, 1592-95-6, 9H-carbazole, 3-bromo-, NSC 74389, DTXSID00936072
Application
3-Bromo-9H-carbazole serves as a versatile precursor in synthesizing carbazole-based optoelectronic materials for OLED displays and lighting systems. Researchers employ it to develop hole-transporting layers in photovoltaic devices due to its electron-rich aromatic system. The compound also finds use in pharmaceutical intermediates and as a ligand in catalytic systems for cross-coupling reactions.
If you are interested or have any questions, please contact us at support@atomfair.com