For synthetic chemists, understanding the reactivity of a chemical intermediate is key to unlocking its full potential. 2-Bromo-6-(trifluoromethyl)quinoline, bearing CAS number 1101205-26-8, is a highly functionalized quinoline derivative whose reactivity is shaped by its key substituents: a bromine atom and a trifluoromethyl group. This article aims to provide a practical guide for chemists looking to buy and utilize this versatile building block in their synthetic endeavors.

Understanding the Core Structure and Substituents
The molecule's foundation is the quinoline ring, an aromatic heterocycle. Attached to this core are two critical groups: a bromine atom, typically at the 2-position in this context (though variations exist), and a trifluoromethyl (CF₃) group, usually at the 6-position. The trifluoromethyl group is strongly electron-withdrawing, which significantly influences the electron density distribution across the quinoline system, often making the ring system more electrophilic and altering the basicity of the nitrogen atom. The bromine atom, meanwhile, is a good leaving group and a versatile handle for numerous transformations.

Key Reactions Involving the Bromine Atom
The bromine atom in 2-Bromo-6-(trifluoromethyl)quinoline is the primary site for many valuable synthetic operations. Its position on the electron-deficient quinoline ring enhances its reactivity in several ways:

  • Palladium-Catalyzed Cross-Coupling Reactions: This is arguably the most significant area of reactivity. The bromine can readily participate in reactions like:
    • Suzuki-Miyaura Coupling: Reaction with organoboronic acids or esters to form new carbon-carbon bonds. This is a cornerstone of modern synthesis for creating biaryl or vinyl-aryl linkages.
    • Stille Coupling: Reaction with organostannanes, another robust method for C-C bond formation.
    • Heck Reaction: Coupling with alkenes to form substituted alkenes.
    • Sonogashira Coupling: Reaction with terminal alkynes to form alkynylated quinolines.
    • Buchwald-Hartwig Amination: Formation of C-N bonds by reacting with amines, crucial for synthesizing pharmacologically active compounds.
  • Halogen-Metal Exchange: Treatment with organolithium or Grignard reagents can lead to halogen-metal exchange, generating a highly reactive organometallic species that can then be quenched with various electrophiles (e.g., CO₂, aldehydes, ketones) to introduce new functional groups.
  • Nucleophilic Aromatic Substitution (SNAr): While less common for aryl bromides compared to activated aryl chlorides or fluorides, under specific harsh conditions or with highly potent nucleophiles, SNAr might be achievable, especially if further activating groups are present.

Impact of the Trifluoromethyl Group
The trifluoromethyl group, beyond its electronic influence, can also impact steric interactions and solubility. Its presence can direct regioselectivity in further electrophilic aromatic substitution reactions on the quinoline ring, though such reactions might be challenging due to the overall electron-deficient nature imparted by CF₃. The CF₃ group is generally very stable and resistant to most reaction conditions, making it an enduring feature in the synthesized molecules.

Sourcing and Practical Considerations
For chemists aiming to purchase 2-Bromo-6-(trifluoromethyl)quinoline (CAS 1101205-26-8), sourcing from reputable manufacturers is key to ensuring the purity (≥97%) and reactivity expected for these transformations. Reliable suppliers, often based in China, provide this intermediate with consistent quality. When planning your synthesis, consider the palladium catalyst loading, ligand choice, base, and solvent for optimal cross-coupling yields. Understanding these reactive pathways allows researchers to efficiently buy and utilize this chemical for their specific synthetic goals.