Atomfair Iridium bromide (IrBr3) Br3Ir

Description Iridium Bromide (IrBr3) is a high-purity inorganic compound with the molecular formula Br3Ir, widely utilized in advanced chemical research and industrial applications. This dark brown to black crystalline solid exhibits excellent stability under standard conditions, making it a preferred choice for catalytic and material science studies. With a CAS number of 317828-27-6, our Iridium Bromide is rigorously tested to ensure superior quality, minimal impurities, and consistent performance. It is available in various quantities, packaged under inert conditions to preserve its integrity. Ideal for researchers and scientists working in catalysis, electrochemistry, and nanotechnology, this compound is a critical reagent for…

Description

Iridium Bromide (IrBr₃) is a high-purity inorganic compound with the molecular formula Br₃Ir, widely utilized in advanced chemical research and industrial applications. This dark brown to black crystalline solid exhibits excellent stability under standard conditions, making it a preferred choice for catalytic and material science studies. With a CAS number of 317828-27-6, our Iridium Bromide is rigorously tested to ensure superior quality, minimal impurities, and consistent performance. It is available in various quantities, packaged under inert conditions to preserve its integrity. Ideal for researchers and scientists working in catalysis, electrochemistry, and nanotechnology, this compound is a critical reagent for synthesizing novel iridium-based complexes and materials.

CAS No: 317828-27-6
Molecular Formula: Br3Ir
Molecular Weight: 431.93
Exact Mass: 431.71589
Monoisotopic Mass: 429.71794
IUPAC Name: tribromoiridium
SMILES: Br[Ir](Br)Br
Synonyms: Iridium tribromide, Iridium bromide (IrBr3), EINECS 233-174-3, DTXSID3064932, DTXCID9032539

Application

Iridium Bromide (IrBr₃) is primarily used as a precursor in the synthesis of iridium-based catalysts for organic transformations and electrochemical applications. It serves as a key material in the development of advanced oxidation processes and fuel cell technologies due to its redox-active properties. Researchers also employ IrBr₃ in the study of coordination chemistry and the fabrication of nanomaterials with tailored electronic and optical characteristics.

If you are interested or have any questions, please contact us at support@atomfair.com