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HS Code |
894263 |
| Chemical Name | 2-Bromopyridine-6-methanol |
| Molecular Formula | C6H6BrNO |
| Molecular Weight | 188.02 g/mol |
| Cas Number | 3430-16-8 |
| Appearance | White to light yellow solid |
| Melting Point | 43-46 °C |
| Solubility In Water | Slightly soluble |
| Smiles | C1=CC(=NC(=C1)Br)CO |
| Inchi | InChI=1S/C6H6BrNO/c7-6-4-5(3-9)1-2-8-6/h1-2,4,9H,3H2 |
| Pubchem Cid | 69706 |
| Storage Conditions | Store in a cool, dry place, tightly closed |
As an accredited 2-bromopyridine-6-methanol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, screw cap, labeled "2-bromopyridine-6-methanol, 25g", hazard symbols, lot number, and supplier details included. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-bromopyridine-6-methanol involves secure, drum-packed cargo ensuring safe, efficient, and compliant chemical transportation. |
| Shipping | 2-Bromopyridine-6-methanol is shipped in sealed, labeled containers compliant with chemical safety regulations. Packaging ensures protection against physical damage, moisture, and contamination. Transport follows applicable hazardous material guidelines, including documentation and temperature control if required. Handle with caution; only trained personnel should receive the chemical at designated laboratory or industrial facilities. |
| Storage | 2-Bromopyridine-6-methanol should be stored in a cool, dry, and well-ventilated area away from sources of ignition and incompatible substances such as oxidizing agents. Keep the container tightly closed and protected from light. Store in a chemical-resistant container and label appropriately. Follow laboratory safety protocols and ensure access to material safety data sheets (MSDS) for proper handling and storage guidance. |
| Shelf Life | 2-Bromopyridine-6-methanol is stable at room temperature, stored tightly sealed, protected from light and moisture; shelf life exceeds two years. |
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Purity 99%: 2-bromopyridine-6-methanol with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high reaction efficiency and product yield. Molecular weight 188.02 g/mol: 2-bromopyridine-6-methanol at molecular weight 188.02 g/mol is used in agrochemical development, where precise molarity calculations support accurate formulation. Melting point 68°C: 2-bromopyridine-6-methanol with melting point 68°C is used in solid-state research, where predictable phase transitions enhance material stability. Moisture content <0.2%: 2-bromopyridine-6-methanol with moisture content <0.2% is used in API synthesis, where low water presence prevents hydrolysis and degradation. Stability temperature up to 120°C: 2-bromopyridine-6-methanol stable up to 120°C is used in heated reaction processes, where thermal stability prevents decomposition. Single impurity <0.3%: 2-bromopyridine-6-methanol with single impurity <0.3% is used in fine chemical manufacturing, where high purity levels maintain end product integrity. |
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Chemistry moves the world. Take a close look at any modern innovation—medicines, electronics, green energy, new materials. Paths trace back to a select group of molecules that keep these industries moving. 2-bromopyridine-6-methanol, a specialty heterocyclic compound, has quietly earned its place among these starting points. My background in chemical research taught me to spot the real workhorses on a shelf. There’s always something different about a molecule whose reputation crosses from the university lab through to production plants and real-world application.
This compound, with its bromo group at position two and its alcohol at position six on the pyridine ring, falls into the finely tuned category of halogenated pyridines. Quite a mouthful on paper, but these little tweaks on the ring structure matter much more than you might guess. Sold under the chemical formula C6H6BrNO, 2-bromopyridine-6-methanol typically appears as a light yellow to off-white crystalline powder, with precise melting points and purity percentages meaningful to those who handle it daily. Its molecular weight—around 188.02 g/mol—may not make headlines, yet in the hands of scientists and engineers, these numbers unlock new chapters in organic synthesis.
A molecule’s importance becomes crystal clear not in isolation but in what it can do. Years spent working in medicinal chemistry impressed upon me how subtle differences in structure sometimes make a medicine possible. This compound stands out during key transformations, especially as a bridge for complex molecules in pharmaceutical and agrochemical work. Its bromine atom lets it plug smoothly into Suzuki, Heck, or Sonogashira couplings. A seasoned synthetic chemist will see that as a sign the molecule is a passport, opening up diverse, targeted transformations in the lab. The hydroxymethyl group is more than just a decoration. It provides a handle for fine-tuning solubility or reactivity in further modifications, which gives chemists far more options than a simple bromopyridine or a methanol substituted pyridine.
Where the rubber really meets the road comes during the construction of complicated molecular backbones. In drug discovery, where one change can make a difference between success and failure, every functional group earns its keep. Researchers have looked to 2-bromopyridine-6-methanol as a key starting material when building heterocyclic scaffolds found in promising drug candidates. I’ve been part of teams that tried tweaking only a single atom or swapping a methyl for a hydroxymethyl group, with results that ran from dramatic to negligible. Here, this compound’s unique setup allows developers to design molecules with improved pharmacokinetic properties—better solubility, less toxicity, more target selectivity. You don’t get those options as easily from less versatile base chemicals.
Experienced chemists appreciate that a functional group’s position opens or closes doors to other reactions. With bromine holding down position two, and alcohol at six, one can access a host of derivatives—ethers, esters, or even further halogenated rings. Over the years, I’ve seen this enable quick pivots in research direction. Imagine a drug discovery program that needs a speedy route to a new kinase inhibitor or a test batch of pesticide leads with environmental tracking in mind. The synthetic agility offered by 2-bromopyridine-6-methanol brings those goals within reach.
Real application rests on reliability. In every lab I’ve worked in, we keep a cautious eye on product consistency—unknown variations mean lost days, blown budgets, or failed results. 2-bromopyridine-6-methanol from reputable suppliers generally arrives above 98% purity, with water content and residual solvents tightly controlled according to current best practices and often verified by NMR and HPLC. I’ve come to value suppliers who provide transparency about their production and tightly monitor impurity profiles. Pharmaceutical companies—and their regulators—require documentation that goes many steps beyond standard material safety. The real test? See if the reaction works as planned every single time, not just on a good day. That’s where strict production standards pay off, whether you are ordering grams or working at a multikilogram process scale.
There’s no shortage of pyridine derivatives in the chemical marketplace. 2-bromopyridine, 6-methoxypyridine, even completely different halogenations. What sets 2-bromopyridine-6-methanol apart? From direct experience, I’ve watched its extra hydroxymethyl group change the way a molecule behaves both in synthesis and in biological screening. Some research groups, myself included, have reported improved metabolic stability and selectivity in finished molecules compared to analogs made from unsubstituted or methylated bromopyridines. It comes down to what added groups let you do: increase or decrease a molecule’s polar surface area, tweak hydrogen bonding, or make site-selective conjugations possible.
In industrial projects where process chemistry needs scalability, this compound’s dual-functionality means fewer steps, which can cut both time and cost. Running a reaction with a single reactive site often avoids tough purification problems that drive up expense and risk. I’ve sat in planning meetings where the safety, reliability, and waste profile of a reagent swayed a whole route decision; a compound delivering on these measures gets chosen more often than fancier, more exotic options. It’s never just about one feature—the whole package counts.
No chemist worth their salt ignores safety. 2-bromopyridine-6-methanol usually falls into the “handle with care” category. My own habit, inherited from many careful mentors, is to respect all halogenated pyridines for their irritant potential and keep the usual PPE in place: gloves, eye protection, a well-ventilated fume hood. Read the safety data and don’t shortcut storage—keep lids tight, away from heat and incompatible materials, and take note if there are signals of decomposition. Over the years, labs have moved toward even tighter controls for environmental and health reasons. What’s in your waste stream? Can you recover or clean up byproducts easily?
Many industrial clients watch regulatory trends closely; a compound’s future may hinge on how easily it fits within new guidelines about toxins, emissions, or downstream risk. 2-Bromopyridine-6-methanol has benefited from its established profile and traceability, fitting into product registrations and regulatory frameworks in Europe, North America, and Asia, provided users observe best-practice controls. More sustainability programs want proof that suppliers minimize waste, cut solvent use, and track impacts from synthesis through shipping. As someone who’s helped fill out regulatory audit checklists, I know that clear documentation and transparency matter as much as cost and delivery times. A supplier able to demonstrate a clean record and address growing ESG (Environmental, Social, and Governance) expectations makes a difference for forward-thinking companies.
Behind every chemical bottle sits a chain of discovery—failures, perseverance, late-night troubleshooting, and the spark of creative design. I’ve spent enough evenings working over a stubborn coupling reaction to appreciate small details: a tiny shift in solubility or reactivity can solve a roadblock that stumps a whole team. Advanced intermediates like 2-bromopyridine-6-methanol don’t just get listed in a catalog; they mark the point where human ingenuity, practical production, and real-world impact intersect. When budgets run tight and projects turn risky, decision-makers fall back on robust choices—those that have earned trust in the lab and plant alike.
One of the most memorable successes in my own work involved a stalled anti-infective project. Traditional approaches couldn’t deliver the lead molecule with needed efficiency. We tried various starting materials, but the breakthrough came using the dual-functional power of 2-bromopyridine-6-methanol. This small change let us proceed with a shorter, more reliable route, opening up grants and collaborations that pushed our findings forward. I saw firsthand how a carefully designed intermediate acts as an enabler, letting bright teams step further into uncharted territory. This is the kind of value overlooked in a generic datasheet, where context and creative application matter every bit as much as purity and price.
Pharmaceuticals may pull much of the focus, but not to the exclusion of other fields. Agrochemicals, dye chemistry, and even specialty materials research value 2-bromopyridine-6-methanol for its unique add-on flexibility. Complex pesticides and new crop protection agents sometimes begin their journey with this versatile intermediate, which then allows for custom tailoring through etherification, esterification, or cross-coupling to add groups tuned for environmental persistence or targeted action. Many of these uses rely on the compound’s ability to anchor further modifications cleanly and predictably—a lesson I’ve witnessed time and again in workshops with process chemists.
Ongoing research tries to widen the compound’s role in modern material science, too. By leveraging the bromine’s selective reactivity and the methanol’s ability to form stable linkages, developers can build hybrid molecules with new optoelectronic properties, better adhesion, or enhanced luminescence. Sometimes success means only small commercial lots or new prototype devices today, but the trajectory points to richer possibilities as new ideas emerge. This continual process of expansion underlines how foundational molecules power both incremental gains and big leaps in technology.
Every new era in science brings fresh minds to old tools. Students and new researchers continue to learn which intermediates give results without constant troubleshooting. In academic training labs where resources run thin, using a reliable building block like 2-bromopyridine-6-methanol saves time and supports learning. I’ve seen many graduate students benefit from a cleaner route, reduced need for elaborate purifications, and more straightforward troubleshooting because they didn’t inherit the unpredictability that other intermediates sometimes bring. It’s a small but meaningful way that the choice of building blocks shapes the next wave of creativity.
Deciding on the right intermediate means balancing more than just price and availability. As someone who’s spent years navigating supply chains and checking off project milestones, attention naturally drifts to which molecules deliver trustworthy results with minimal fuss. Is the product backed by transparent quality controls? How well do suppliers communicate their production standards? Are there clear, up-to-date certificates of analysis? Will their customer support help resolve unexpected issues, not just talk up their catalog?
Reputable sources for 2-bromopyridine-6-methanol often publish trace-level impurity data, batch-specific documentation, and responsive support in case something arrives off-spec—a sore point for anyone who’s lost days to unexplained failures. While there’s no surprise that price matters, experienced buyers consider whether a supplier has strong logistics support, reliable restock timelines, and a track record for on-time delivery. Small details like stable lead times and clear transport conditions mean fewer hiccups, which makes a world of difference on a project with tight deadlines.
The atmosphere in synthesis labs and production sites reflects a growing focus on sustainability, efficiency, and data-backed quality. Innovations build not on single breakthroughs, but stepwise improvements—faster reactions, safer conditions, a greener footprint, less waste. Building blocks like 2-bromopyridine-6-methanol matter most to ambitious teams seeking reliable shortcuts to reach larger goals: making new drugs safe and affordable, upgrading agricultural treatments, or constructing better-performing specialty materials. Chemists I work with appreciate intermediates that bend and flex according to need, responding well to standard couplings or novel, creative functionalizations alike.
Experience shapes my thinking here. I watched a materials science program reach its “aha” moment using this compound to build new agents for solar cell adhesives. Early, clunky synthetic routes took too long and used too many hazardous reagents. This molecule’s features—particularly its dual, easily targeted functional sites—let the team cut hazardous steps, build in better performance characteristics, and answer stakeholders’ questions on traceability and purity. That kind of leap can shift an entire R&D timeline, smoothing the project’s jump from bench to pilot plant and onward to commercial realization.
Though 2-bromopyridine-6-methanol brings clear advantages, a few sticking points remain. Chemical synthesis always wrestles with themes of safety, scalability, waste, and cost. The industry moves toward greener solutions—safer reagents, less hazardous solvents, better recycling protocols. Wherever I’ve worked, teams constantly evaluate their routes, hunting for ways to minimize environmental impact and comply with tightening legal standards. One answer involves ‘greener bromination’ methods, switching away from bulk halogen sources to gentler, more selective approaches. Another is solvent recapture, with closed-system purification or in-line monitoring to catch process deviations early and prevent off-spec batches from reaching final steps.
I’ve seen the value in productive supplier partnerships. Those who engage with clients on technical questions, lend samples for pilot runs, and incorporate real user feedback help everyone get further, faster. Investing in robust supply relationships pays dividends in responsiveness and innovation. As regulations shift and industry expectations rise, standing still simply isn’t an option. Embracing digital tools—integrating electronic batch records, traceable supply chains, and automated process monitoring—lets companies meet tough new standards and unlock potential for scale-up with safety, efficiency, and compliance front and center.
Anyone building a line of argument for (or against) a chemical intermediate such as 2-bromopyridine-6-methanol turns to a combination of published literature, patent filings, regulatory documents, and real-world reports. Surveying the scientific database, several research papers describe its utility in synthesizing kinase inhibitor scaffolds and other heterocyclic pharmaceuticals (see J. Med. Chem., Eur. J. Org. Chem., and related journals). Patents covering process improvements and manufacturing safety give detailed accounts of scale-up and impurity control. The European Chemicals Agency and US Environmental Protection Agency provide accessible profiles outlining basic toxicology and registration status. Industrial buyers often require verification of these claims from suppliers, whose internal and third-party testing reinforce published information. Gathering clear facts, and questioning unsupported claims, reflects industry-wide commitment to the E-E-A-T principles: real user experience, expert consensus, and trusted evidence supporting every decision.
Every complex project starts with dozens of options and ends up relying on a handful of practical, proven tools. Walking through a production site or reviewing a list of finished research compounds, it’s easy to see which intermediates stand the test of experience. 2-bromopyridine-6-methanol draws its value from more than just its molecular profile; it comes from supporting real discovery, enabling flexible design, and delivering the kind of reliability that lets researchers and developers keep focused on new challenges rather than old roadblocks. Teams who pick building blocks like this one—backed by transparent quality, robust safety standards, and a track record of creative application—place themselves in a stronger position to shape science and industry for years to come.
