Organic chemistry is a vast field, and within it, brominated organic compounds hold a special significance. The presence of a bromine atom in an organic molecule often imparts unique reactivity and properties, making them indispensable tools in chemical synthesis. These compounds serve as vital building blocks for a wide array of complex molecules used across various industries.

Hydroxylamine, O-[(3-bromophenyl)methyl]-, hydrochloride (CAS 159023-41-3) is a notable example of a brominated organic compound with considerable synthetic utility. Characterized as a white powder with 98% purity, its structure features a bromine atom attached to a phenyl ring, alongside a hydroxylamine moiety. This combination of functional groups makes it a valuable intermediate in organic synthesis, particularly for creating more complex pharmaceutical agents, diagnostic reagents, and specialized chemicals.

The utility of brominated organic compounds often stems from the carbon-bromine bond. Bromine is a good leaving group, facilitating nucleophilic substitution reactions. This characteristic is heavily exploited in chemical synthesis, allowing for the introduction of various other functional groups onto the molecule. For instance, the 3-bromophenyl group in this compound can be further modified through cross-coupling reactions, such as Suzuki or Sonogashira couplings, to build larger molecular frameworks.

The pharmaceutical intermediates usage of such brominated compounds is extensive. They are often used in the early stages of drug synthesis to introduce specific structural elements or to act as reactive handles for subsequent transformations. The reliable purity 98% chemical of compounds like Hydroxylamine, O-[(3-bromophenyl)methyl]-, hydrochloride sourced from suppliers such as NINGBO INNO PHARMCHEM CO.,LTD is critical for reproducible and successful synthesis pathways.

Beyond pharmaceuticals, brominated organic compounds also find applications in flame retardants, agrochemicals, and materials science. The specific properties imparted by the bromine atom can be tailored to meet the demands of these diverse applications. The price of these compounds can fluctuate based on market demand, synthesis complexity, and bromine availability, but their unique reactivity often justifies their cost.

When researchers or manufacturers look to buy Hydroxylamine O-(3-bromophenyl)methyl hydrochloride, they are often seeking a specific building block with a well-defined reactive site. The presence of bromine, coupled with the hydroxylamine group, offers multiple avenues for chemical modification. The chemical compound appearance white powder is a visual indicator, but the true value lies in its controlled reactivity.

The ongoing research in synthetic organic chemistry continually reveals new ways to utilize brominated organic compounds, expanding their applications in areas like medicinal chemistry and material science. The ability to synthesize these molecules efficiently and with high purity remains a key focus for chemical manufacturers.

In conclusion, brominated organic compounds like Hydroxylamine, O-[(3-bromophenyl)methyl]-, hydrochloride are indispensable tools in the chemist's arsenal. Their versatile reactivity, enabled by the carbon-bromine bond, makes them critical intermediates for innovation across pharmaceutical, diagnostic, and material science sectors.