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HS Code |
818588 |
| Product Name | 3-BROMO-2-METHOXYPYRIDINE |
| Purity | 98% |
| Cas Number | 26282-86-2 |
| Molecular Formula | C6H6BrNO |
| Molecular Weight | 188.02 g/mol |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 220-222°C |
| Density | 1.56 g/cm3 at 25°C |
| Flash Point | None recorded |
| Refractive Index | 1.5550-1.5590 |
| Storage Conditions | Store at 2-8°C |
| Smiles | COC1=NC=CC(=C1)Br |
| Synonyms | 2-Methoxy-3-bromopyridine |
| Ec Number | 226-128-9 |
As an accredited 3-BROMO-2-METHOXYPYRIDINE ,98% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of 3-Bromo-2-methoxypyridine, 98%, with a tamper-evident cap and chemical hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Bromo-2-methoxypyridine, 98%: Secure packaging, moisture protection, proper labeling, and regulatory compliance for safe international shipping. |
| Shipping | 3-Bromo-2-methoxypyridine, 98% is shipped in sealed, chemical-resistant containers to ensure stability and safety. It is packed in accordance with international regulations for hazardous materials, with proper labeling and documentation. The package is protected against moisture, light, and impact, with expedited delivery typically available for research and laboratory use. |
| Storage | 3-Bromo-2-methoxypyridine, 98%, should be stored in a tightly sealed container in a cool, dry, well-ventilated area away from incompatible substances such as strong oxidizers and acids. Protect from moisture and direct sunlight. Store at room temperature, and ensure proper chemical labeling. Use appropriate personal protective equipment when handling, and follow all relevant safety protocols for hazardous chemicals. |
| Shelf Life | Shelf life of 3-Bromo-2-methoxypyridine, 98%: Typically stable for 2-3 years when stored in a cool, dry, airtight container. |
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Synthesis Intermediate: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in pharmaceutical synthesis, where high purity ensures selective reaction pathways. Purity %: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in agrochemical intermediate production, where consistent 98% purity yields reproducible product quality. Melting Point: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in research laboratories, where a defined melting point facilitates accurate compound identification. Stability Temperature: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in medicinal chemistry, where high thermal stability allows safe reaction condition optimization. Molecular Weight: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in analytical chemistry, where precise molecular weight supports quantitative assay development. Solubility: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in organic synthesis, where good solubility in common solvents improves process scalability. Reactivity: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in heterocyclic compound modification, where controlled bromine reactivity supports targeted functionalization. Storage Stability: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in chemical libraries, where robust storage stability maintains compound integrity for extended periods. Spectroscopic Purity: 3-BROMO-2-METHOXYPYRIDINE ,98% is used in NMR studies, where high spectroscopic purity enables clear structural analysis. |
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Understanding chemicals often feels complicated, although anyone in synthetic chemistry or drug development knows how much hinges on finding the right building blocks. 3-BROMO-2-METHOXYPYRIDINE, 98% has carved out its own corner in labs and small-scale plants where attention to detail makes all the difference. This compound isn’t just another name on a bottle; it represents a specific solution to challenges chemists and researchers face when exploring the pyridine scaffold.
I remember sitting with a colleague over a pile of synthetic route ideas, hunting for intermediates that would provide cleaner paths and better yields. 3-BROMO-2-METHOXYPYRIDINE stood out for several reasons. With a methoxy group on the second carbon and a bromo substituent on the third, this molecule offers a unique combination of properties. The methoxy group provides electron donation, making some chemical transformations happen where other pyridines stall. The bromo group, on the other hand, gives synthetic chemists a hook for coupling reactions, especially if someone relies on palladium-catalyzed cross-couplings. Watching a Suzuki-Miyaura coupling come together with this compound, I learned how a single halide can shift a project from dead end to possibility.
98% purity shows someone cared about cleaning up the product after synthesis. This makes life easier down the line, whether running a library of candidate compounds or fixing a bottleneck in manufacturing. Any bench chemist who has spent an afternoon purifying low-grade materials only to watch yields disappear down the drain learns to appreciate a reliable, high-purity supply. The cost of time lost cleaning up shoddy reactants adds up. I don’t miss those days.
One thing I appreciate about the world of specialty chemicals is how diverse the uses get, even for a molecule like 3-BROMO-2-METHOXYPYRIDINE. Most frequently, I’ve seen it provide the starting point for building complex molecules in both medicinal and agricultural research. Chemists working in heterocyclic chemistry grab this molecule when a simple pyridine doesn’t offer enough to move a synthesis forward. Introducing a bromo group expands the toolkit for transformations like Buchwald-Hartwig amination, allowing people to modify the backbone and assemble novel structures.
Teams racing to discover new pharmaceuticals use these kinds of compounds to tweak the activity of their lead molecules. One day it goes into a drug candidate aiming for antibacterial properties, another day it finds itself part of a new molecule the scientists hope will treat inflammation. The patterns of substitution across the pyridine ring mean 3-BROMO-2-METHOXYPYRIDINE can influence both solubility and binding at the target site. This is not just theory—people spend late nights in labs trying out substitutions to reach that ‘sweet spot’ between potency and drug-like properties.
Agricultural chemists, too, turn to this molecule for its convenience in making new herbicide scaffolds. The bromo group often acts as a placeholder, later swapped through nucleophilic substitution for groups tailored to field performance. Because of the methoxy group’s tendency to increase certain biological activities, researchers keep reaching for this combination when designing compounds to outpace resistance in weed populations.
It’s easy to underestimate the role of purity until you’ve worked through enough failed reactions. Years back, a batch came through with contaminants above routine levels, and results turned unpredictable. The difference between 95% and 98% purity translates into less troubleshooting, better batch-to-batch reproducibility, and more confidence at every scale. Contaminants can poison catalysts or lead to unwanted byproducts, which wastes not only reactants but also the time of the people running the experiments.
The 98% figure on this product means most synthetic routes run cleaner, and the downstream analytical work gets simpler. It’s one less variable for R&D scientists to track. For those working on kilogram lots—especially as projects move into process development—higher purity affects regulatory filings and eventual commercialization. Having seen drug development teams stumble because batches didn’t meet impurity profiles, I’ve learned to value suppliers who take quality seriously at every stage.
To really grasp what sets 3-BROMO-2-METHOXYPYRIDINE apart, it helps to compare it with other functionalized pyridines. Try running a reaction that needs both electron-rich and reactive positions, and you’ll soon see why chemists prefer this structure. Substituting at the second carbon with a methoxy group changes electron flow in the ring, so downstream couplings or substitutions look different compared to methyl or halogen-only pyridines.
Some labs use 2-bromopyridine as a base compound, but without the methoxy group, reactivity changes. Selectivity in reactions shifts, yields fluctuate, and time-consuming purifications reappear. Those working on combinatorial libraries appreciate the subtle but significant impact this structural tweak has on the formation of key bonds. Plus, not every bromo-pyridine is equally friendly for coupling reactions; the position of the bromine makes a difference. This molecule gives chemists a new angle for creating diversity in their candidate sets.
Another clear contrast crops up during scale-up. Less complex compounds may work fine on milligram scale, but start failing or producing more impurities when you scale to grams or kilograms. I once watched two projects—one starting from a simple methylpyridine and another from 3-BROMO-2-METHOXYPYRIDINE—play out side-by-side. The project using this more specialized intermediate moved through kilo-scale trials with fewer hiccups, and process validation happened faster.
What drew me to molecules like this was always the intersection between challenge and possibility. Lab records tell stories most chemical suppliers don’t mention: the late hours troubleshooting weird side-products or chasing down why a yield dropped from 78% to 33% in a single experiment. Having an intermediate like 3-BROMO-2-METHOXYPYRIDINE in the toolkit has, in my experience, shortened those dark alleys in synthetic planning.
Students new to organic synthesis often overlook the impact of small substituent changes, but anyone sitting through reaction optimization meetings comes to appreciate them. Methoxy groups contribute not just to electron density but often to improved solubility as well, changing the behavior of the entire molecule. The bromo position opens doors to highly selective couplings, giving medicinal chemists a shortcut to otherwise lengthy transformations.
Early-career researchers performing structure-activity relationship studies often look for compounds that let them ‘walk’ around the ring structure, swapping in different functional groups at strategic spots. Starting with a 3-bromo substituted compound makes this process simpler. It’s not a magic bullet, but it’s a notable improvement over blank-slate synthesis, especially if you’re fighting for efficiency.
Many people outside the chemical industry might not realize the larger implications of what happens in these synthetic steps. Purity and precise substitution patterns aren’t just technical debates—they influence everything from project timelines to overall research productivity. Think of drug discovery: a poorly chosen intermediate sets back a whole team, rippling out as delays in testing, reporting, and investment.
From my years around startup biotech labs, I’ve seen what happens when supply chain hiccups or inconsistent batch quality from suppliers throw off an otherwise well-planned development cycle. That 2% difference in purity is the buffer between smooth progress and costly diagnostic workups. As global supply chains stretch thinner and regulations become tighter, teams depend more than ever on compounds that consistently meet strict standards.
Consider environmental health as well. The reduction in byproducts and waste that comes with high-purity intermediates means safer working conditions and less chemical waste to process. More efficient reactions lower energy use over time, which is no small thing in an industry always pressed about its environmental footprint. Small improvements made upstream compound into larger downstream gains across the entire sector.
Industry analyses tracking pharmaceutical and agrochemical intermediate markets consistently note growth in demand for halogenated pyridines and their derivatives. Published literature highlights frequent use of 3-BROMO-2-METHOXYPYRIDINE-like compounds in new reaction methodologies, from palladium-catalyzed couplings to direct functionalizations that create whole families of therapeutic possibilities.
Peer-reviewed articles in journals such as the Journal of Organic Chemistry and European Journal of Medicinal Chemistry report on structure-activity trends involving methoxypyridine cores, and this specific substitution pattern often recurs in patents claiming next-generation herbicides or drug candidates. Reliable suppliers offering 98% purity see continued orders because researchers trust them through all stages of R&D.
According to comprehensive chemical databases, demand for advanced heterocycles like this one grows with each uptick in complexity of new pharmaceutical classes. This compound’s availability at high quality sets a higher bar for both academic and commercial projects, as researchers globally seek advantages in increasingly competitive fields.
If there’s one thing researchers can do to keep projects running smoother, it’s choosing intermediates with proven track records like 3-BROMO-2-METHOXYPYRIDINE, 98%. It’s not enough to check a box for reactivity; the broader impact on project scheduling, reproducibility, and environmental performance all come into play. Reliable sourcing keeps surprises to a minimum and lets teams focus on developing the best science, not firefighting avoidable problems.
On the manufacturing side, suppliers who back their purity claims with certificates of analysis and robust quality control build trust that pays off in long-term partnerships. Distribution chains working to keep product integrity intact—from production to delivery—serve both research and commercial interests. Labs standing at the front of innovation gain from knowing they’ll receive the same profile every time, cutting down on documentation headaches and unexpected troubleshooting.
Researchers themselves have a role to play by documenting every step where high-purity reactants lead to significantly better outcomes. Sharing these stories in published methods and process chemistry meetings builds a library of practical knowledge accessible to the entire field. The extension of these experiences through collaboration and peer review raises standards for everyone, nudging both academic and industrial practices to higher levels.
The hunt for better medicines and more sustainable agricultural solutions keeps shifting. Today’s core structure is tomorrow’s legacy. Yet compounds like 3-BROMO-2-METHOXYPYRIDINE, which combine reliability with versatility, stay relevant longer. Teams building out new libraries or scaling up winning candidates still turn to these specialized intermediates as shortcuts to otherwise complicated routes.
My own experience echoes what many in this field say: the best research programs succeed not just with good ideas, but with the right materials behind them. The tight margins in both pharmaceutical and agrochemical development mean that reliable, high-purity reagents aren’t just nice-to-have—they are often what makes a new product possible. Every success story in synthesis relies on these quiet workhorses.
Research and development can feel far removed from people, yet every breakthrough begins with individuals making smart, community-driven choices. A well-chosen intermediate like 3-BROMO-2-METHOXYPYRIDINE, 98% shortens the distance between theory and reality. The hours that went into pure, reproducible chemicals create space for quicker learning, deeper investigation, and more chances for discovery. Good chemistry means supporting those who make it happen, not just ticking spec sheets.
Anyone who’s worked a few years in the lab feels the difference between guesswork and confidence. A string of successful reactions powered by reliable intermediates turns skepticism into momentum. Students get more out of their training, senior chemists trust their results, and safety margin builds across the board. The work done to provide pure reagents creates value not just for today’s batch, but for the research culture that stretches between generations of scientific teams.
Sustainable growth in the chemical industry hinges on maintaining quality and keeping up with ever-stricter regulations. As new synthetic strategies emerge, they lean even more heavily on well-characterized building blocks. The story of 3-BROMO-2-METHOXYPYRIDINE, 98% isn’t just about a single compound—it’s part of the larger narrative showing that industry progress follows from technical care, strategic choice, and shared lessons.
For scientists tasked with meeting ambitious targets, the right intermediates give a running start. Whether facing a pressing synthesis problem or scaling up for pilot trials, trusting in robust reagents frees up time and energy for solving the next challenge. As long as chemists keep asking for better, more precise solutions, compounds like this will hold a key role on the bench and beyond.
So much of scientific progress is invisible. The stories that don’t get told often involve a dozen dead-ends, abandoned syntheses, and late nights hoping the next run will hold together. In every successful pathway, core intermediates such as 3-BROMO-2-METHOXYPYRIDINE, 98% provide the quiet structure underlying all the visible results. Progress comes by stacking together smart choices in sourcing, synthesis, and documentation.
In my experience, every time the right material showed up on time and in spec, it amplified the efforts of skilled and creative researchers. That’s why stories from the lab rarely end with the final step; they roll forward with each intermediate selected for its effect on speed, safety, and the possibility of breakthrough. There’s a reason people keep returning to this compound: it works, and that matters more than any slogan or spec sheet ever could.
