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HS Code |
263465 |
| Chemical Name | 5-Bromo-2-Methylbenzoxazole |
| Molecular Formula | C8H6BrNO |
| Molecular Weight | 212.04 g/mol |
| Cas Number | 156074-07-6 |
| Appearance | Off-white to light yellow solid |
| Melting Point | Estimated 95-99°C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Purity | Typically ≥ 98% |
| Storage Conditions | Store in a cool, dry place |
| Synonyms | 5-Bromo-2-methyl-1,3-benzoxazole |
| Smiles | Cc1nc2ccc(Br)cc2o1 |
| Inchi | InChI=1S/C8H6BrNO/c1-5-10-8-4-2-3-6(9)7(8)11-5/h2-4H,1H3 |
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The world of benzoxazoles offers a deep well of discovery for anyone invested in chemical development. Spotting something different can often mean the difference between an ordinary product and the competitive edge that research, pharmaceuticals, and specialty industries look for. 5-Bromo-2-Methylbenzoxazole (also called 5-bromo-2-methyl-1,3-benzoxazole) stands out in this area thanks to its unique chemical profile, reliable performance, and adaptability.
5-Bromo-2-Methylbenzoxazole enters the market with a distinct structure: it positions a bromine group at the fifth carbon and a methyl group at the second carbon on the benzoxazole ring. These modifications matter. Bromination at the fifth site creates new reactive possibilities, especially for those in pharmaceutical R&D. The methyl group brings added hydrophobicity, nudging this compound into zones where standard benzoxazoles tend to fall short. Both features change the molecule’s physical and electronic character, making it useful in applications where small changes in structure drive big functional differences.
Looking closely at available materials, purity matters as much as structure. Leading chemical suppliers deliver this compound with high purity, usually above 98%, removing much of the troubleshooting that comes with less refined options. The melting point falls within a predictable range for benzoxazoles, a detail that may seem technical, but in the lab, it lets chemists trust the consistency of their inputs. Since every variable counts in complex synthesis, the combination of confirmed purity and specified structure gives users a secure foundation for their projects.
Direct experience shows that 5-Bromo-2-Methylbenzoxazole responds well during reactions involving cross-coupling or further functionalization, especially in Suzuki or Buchwald-Hartwig reactions. That bromine atom opens up possibilities for introducing new side chains, linking it to other rings, or attaching it to diverse frameworks. The methyl group’s presence influences both solubility and reactivity, which can shape the direction of the entire experimental workflow.
These features often come into play in medicinal chemistry, where minor tweaks can spawn dramatic changes in a compound’s pharmacological profile. Researchers running SAR (structure-activity relationship) studies on benzoxazole scaffolds can experiment with this product to push the boundaries of selectivity and potency in pharmaceuticals. My own time in the lab often showed that access to these bromo/methyl analogs speeds up cycles of synthesis and testing, cutting down on wasted time and avoidable surprises.
Benzoxazoles as a category draw chemists for their aromatic stability, ability to participate in hydrogen bonding, and general versatility. 5-Bromo-2-Methylbenzoxazole lands in the sweet spot for specialists looking to expand their synthetic options beyond plain benzoxazole or its simple halogenated forms. While a 5-bromo-benzoxazole is not unusual in catalogs, adding the methyl group brings in an extra level of functional variety.
Selecting between 5-Bromo-2-Methylbenzoxazole and a basic 2-methylbenzoxazole can have far-reaching effects. In my experience, introducing a bromine at the right spot speeds up multi-step syntheses through reliable cross-coupling, something not possible with most unsubstituted compounds. Substituted benzoxazoles like this one are also less likely to suffer from metabolic instability in early biological studies, pointing to some of the practical advantages that come from these subtle design tweaks.
In my work with academic and industrial chemists, 5-Bromo-2-Methylbenzoxazole often shows up as a stepping stone in the journey from base molecule to novel candidate molecule. Many drug discovery projects start with a benzoxazole core. If a facility needs to attach a bulky group or introduce a special function, this product acts as a strong intermediate. The bromine handles cross-coupling while the methyl group pushes solubility in solvents like dichloromethane or ethyl acetate.
For material scientists, 5-Bromo-2-Methylbenzoxazole supplies a building block for advanced polymers or specialty dyes. These applications thrive on molecules ready for modification; the bromine acts as a “handle” for further chemical tailoring. In electronics, such derivatives may end up in organic semiconductors or photoluminescent systems. People working on these projects often talk about the frustrations of sourcing rare building blocks, so it’s a real advantage to have materials like this available with consistent quality and on a reasonable timeline.
Innovation in chemistry rewards those who can stitch together unique molecules. Having access to a product like 5-Bromo-2-Methylbenzoxazole means researchers avoid being boxed into traditional routes. Flexibility in synthesis matters because a single bottleneck can stall an entire program. For those working on patentable molecules, each structural variant is a potential edge—something even a decade of experience keeps teaching me.
Automated systems and high-throughput reactions demand inputs that don’t throw surprises partway through a sequence. Products with documented purity, stability, and supply history become more valuable than ever in these settings. Looking through papers and patents reveals a growing appetite for these custom intermediates. Real progress comes not from bulk base chemicals, but from refined building blocks like this one.
Ethical labs build respect for chemicals through safe storage and careful handling. 5-Bromo-2-Methylbenzoxazole warrants attention on both fronts. Following standard lab protocols—wearing gloves, using a fume hood, and careful weighing—fits with how I and my peers handle benzoxazoles. The typical material shows stability at room temperature away from light and moisture, letting teams avoid the endless cycle of rush orders and lost product. Responsible suppliers back this up with batch quality reports.
Documentation follows the expectations set by the chemical industry and regulatory guidance. Consistent labeling, verified lot analysis, and clear melting point ranges help researchers feel confident. Lab safety comes from a mix of responsible sourcing and daily diligence. A compound that holds up in storage means that talented people aren’t caught out by unexpected degradation.
Chemical development rewards those who watch for incremental improvements. The presence of both bromine and methyl in 5-Bromo-2-Methylbenzoxazole nudges this compound out of the ordinary. New pharmaceuticals, agrochemicals, or advanced functional materials can trace their origins back to these building blocks. Having a reliable route to such a compound means a team saves time and headaches at every step in their synthetic campaigns.
The ability to source this benzoxazole variant with high purity allows chemists, pharmacologists, and engineers to build molecules that go beyond textbook templates. Through strategic use in reaction design, it can reduce the time lost to purification and scale-up problems. This lets projects move from theory to results with fewer interruptions.
Working with 5-Bromo-2-Methylbenzoxazole offers a sense of assurance grounded in practical experience and careful quality control. Each element in its structure speaks to years of trial, error, and improvement in the field. My background indicates that every lab run, synthesis trial, or scale-up grows easier with intermediates that prove themselves batch after batch.
Supplier selection plays a huge role in this confidence. Rather than gambling with unknown or inconsistent sources, professional chemists turn to catalogues that publish quality documentation and respect for user feedback. Problems that crop up from contamination, mislabeling, or missing certificates can shut down a week’s worth of effort. Avoiding those bumps in the road demands not just a good molecule, but a supplier who stands behind its reliability every time.
Much of the utility in 5-Bromo-2-Methylbenzoxazole reveals itself not in a chemical registry or an MSDS, but in the day-to-day flow of work in applied chemistry. Past experience suggests that when a team switches from a generic benzoxazole to this bromo-methyl variant, yields of target compounds rise and purification becomes more manageable. Even small improvements in solubility or reaction clean-up add up, especially in multi-step syntheses or when preparing derivatives for screening or formulation.
Demand for such tailored compounds signals a move in the market from generic to precise. Custom synthesis, once the domain of only the biggest companies, now forms the baseline for specialist teams everywhere. This trend rewards products like 5-Bromo-2-Methylbenzoxazole, which carry enough flexibility to support different applications, yet show the consistency that seasoned chemists rely on.
Problems can arise at any stage, from ordering to use in reactions. Sometimes shipments arrive with minor but irritating variations in melting point or purity percentage—factors that quickly erode trust. Labs solve these problems by building in checks, running purity analyses, and establishing trusted relationships with competent suppliers. Investing a little more up front in a certified product saves vastly more downstream in failed experiments and wasted materials.
Supply chain stability has entered the spotlight in both research and manufacturing. Having a regular, reliable source for specialty intermediates can make or break long-term projects. Establishing dual sources or working with suppliers who carry stock locally shortens lead times and shrinks the risk of interruption. Many research teams don’t realize how dependent they’ve become on single-source chemicals until a supply chain hiccup brings work to a halt.
Another challenge emerges in documentation and regulatory compliance. Researchers working across borders or under tight audit scrutiny often run into hurdles if products lack supporting paperwork. The best way to sidestep these snags comes down to looking past price alone and prioritizing partners who invest in proper documentation from batch to batch.
Interest in 5-Bromo-2-Methylbenzoxazole has reached far beyond traditional lab-scale organic synthesis. For instance, some research groups are building new small-molecule libraries for hit finding in drug discovery, where every variant may lead to a game-changing signal in a high-throughput screen. In agrochemical labs, subtle differences like the presence of a methyl group can shape target specificity and environmental fate. Material science teams wonder if the same structural features will someday turn up in the next generation of organoelectronic materials.
From an educational angle, teaching labs now look for examples that stretch student problem-solving skills beyond basic single-function molecules. 5-Bromo-2-Methylbenzoxazole gives instructors a chance to set problems where protecting groups, coupling strategies, and purification methods all become real-world lessons. In my time mentoring younger chemists, giving them access to such structurally rich compounds helps them grasp the complexity and possibility of modern organic synthesis without sacrificing safety or reliability.
Academic and industrial chemists both deal with the growing emphasis on sustainable practices and responsible sourcing. While no specialty chemical escapes environmental scrutiny, responsible use and waste management guide how compounds like 5-Bromo-2-Methylbenzoxazole fit within larger industry trends. The chemical’s relative stability and manageable hazard profile make it a sensible choice over more exotic, less thoroughly studied intermediates.
Efforts to green the chemical supply chain now stress transparency, not just in what is supplied but in how it reaches researchers. This aligns with what I’ve seen among colleagues: they line up behind suppliers who publish their sourcing practices, keep up to date compliance records, and support users with honest feedback channels. The evolution of research demands that even new, specialty compounds be brought into the fold with a clear eye toward their lifecycle, from catalytic conversion to final waste.
Reflecting on all these factors, 5-Bromo-2-Methylbenzoxazole occupies a niche that continues to grow in value. Its structure, featuring both halogen and alkyl substitution on the benzoxazole ring, means it adapts to a wide range of chemical transformations and downstream applications, from pharmaceuticals to materials. Labs benefit from its purity and documented performance, saving effort on troubleshooting and repeat tests.
The experience of working with this compound highlights how well-made building blocks can shape the pace and quality of innovation. Teams who balance reliability, supply, and smart synthetic options often find themselves at the forefront of their industries, pushing boundaries with help from materials like this one.
Chemical synthesis keeps pushing toward greater precision and versatility. 5-Bromo-2-Methylbenzoxazole brings an uncommon blend of function and dependability, backing up not just new experiments, but the routine, day-to-day steps that allow discovery to flourish. Today’s most exciting projects often begin not with new equipment, but with the right partners and the right molecules delivered on time and in the right condition.
As demands grow more complex across scientific fields, the true worth of advanced intermediates becomes ever clearer. Still, every lab story seems to come back to trust. The more experience teams have with products like this, the more forward-looking their research becomes—building new possibilities, not just for their fields, but for the next generation of scientists and innovators.
