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HS Code |
573919 |
| Name | 3-bromo-6-methylpyridine-2-carbonitrile |
| Cas Number | 884494-34-2 |
| Molecular Formula | C7H5BrN2 |
| Molecular Weight | 197.04 g/mol |
| Appearance | Off-white to pale yellow solid |
| Melting Point | 63-67°C |
| Purity | Typically ≥98% |
| Smiles | CC1=NC(=C(C=N1)C#N)Br |
| Inchi | InChI=1S/C7H5BrN2/c1-5-2-6(8)7(3-9)10-4-5/h2,4H,1H3 |
| Solubility | Slightly soluble in organic solvents (e.g., dichloromethane, ethanol) |
| Storage Condition | Store at 2-8°C, protect from light and moisture |
| Synonyms | 2-Cyano-3-bromo-6-methylpyridine |
As an accredited 3-bromo-6-methylpyridine-2-carbonitrile 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-6-methylpyridine-2-carbonitrile, labeled with chemical name, CAS number, and safety warnings. |
| Container Loading (20′ FCL) | 20′ FCL: 3-bromo-6-methylpyridine-2-carbonitrile securely packed in sealed drums/cartons, maximizing container space for efficient, safe international shipment. |
| Shipping | 3-Bromo-6-methylpyridine-2-carbonitrile is shipped in tightly sealed, chemical-resistant containers to prevent moisture and contamination. Packages comply with relevant chemical transport regulations and are clearly labeled with hazard information. During transit, the chemical is kept in a cool, dry place and handled by authorized personnel to ensure safety and integrity. |
| Storage | 3-Bromo-6-methylpyridine-2-carbonitrile should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as strong oxidizers. Store at room temperature, protected from direct sunlight and moisture. Ensure proper labeling and use appropriate secondary containment to prevent spills or leaks. Handle with suitable personal protective equipment. |
| Shelf Life | Shelf life of 3-bromo-6-methylpyridine-2-carbonitrile is typically 2–3 years if stored in a cool, dry, airtight container. |
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Purity 98%: 3-bromo-6-methylpyridine-2-carbonitrile with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and optimized reaction selectivity. Melting Point 75°C: 3-bromo-6-methylpyridine-2-carbonitrile with a melting point of 75°C is used in organic synthesis workflows, where it allows for precise temperature-controlled processes. Particle Size <50 μm: 3-bromo-6-methylpyridine-2-carbonitrile with particle size less than 50 μm is used in catalyst preparation, where it enables enhanced dispersion and reaction efficiency. Stability Temperature up to 110°C: 3-bromo-6-methylpyridine-2-carbonitrile stable up to 110°C is used in high-temperature coupling reactions, where it maintains chemical integrity and minimizes decomposition. Molecular Weight 199.03 g/mol: 3-bromo-6-methylpyridine-2-carbonitrile with molecular weight 199.03 g/mol is used in analytical research, where it facilitates accurate stoichiometric calculations and reproducible results. |
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Working with 3-bromo-6-methylpyridine-2-carbonitrile means handling more than just another fine chemical on the production board. The molecule itself, with its bromine atom at position three, a methyl group at position six, and a nitrile at position two, packs a lot into a compact structure. That makes a difference for chemists looking to navigate the challenge of building larger, more intricate compounds. We produce this compound with close control over batch consistency and purity because, frankly, downstream steps—be it cross-coupling reactions or ring modifications—don’t forgive sloppy outputs.
From our vantage point, the usability of 3-bromo-6-methylpyridine-2-carbonitrile hinges on specs that labs care about, not just numbers on a COA. A tight melting range and well-managed water content hold big consequences. During synthesis, crystallization doesn’t just happen in theory. In practice, impurities drag batches off-spec and cause headaches nobody wants. We routinely check for those traces—bromide side-products, isomers, and residual solvents—because these get amplified through later synthesis routes and can undermine weeks of effort for our customers.
In manufacturing, "model" doesn’t mean a catalog entry. It means choices about lot sizes, particle size distribution, and packaging. Clients tackling scale-up projects or custom synthesis are looking for a reliable upstream material. Multi-gram research lots and multi-kilogram production runs both roll off the same lines, but we tweak processes and quality controls to fit the scale. The model in our context means learning which customers want high-purity grades for pharmaceuticals and which use more relaxed specs for pigment intermediates. Those adjustments rarely make it into sales brochures but dictate our daily work.
The bromine sits on carbon three for a reason: it's reactive enough for Suzuki, Heck, and other cross-coupling methods, yet it offers selectivity that’s tricky to achieve with other pyridine derivatives. No other halogen or substitution pattern on this ring will mimic the reactivity in a plug-and-play fashion. We take pride in the clean installation of the bromine—ensuring regioselectivity—because even minor byproducts at this position lead to costly process hiccups for chemists in pharmaceutical or agrochemical research.
We see inquiries from pharmaceutical R&D, crop protection companies, and specialty chemical labs. Most of our output heads into early-stage drug candidates, often in nitrogen-rich scaffolds. Researchers pair this compound with a wide range of palladium catalysts, seeking to piece together functionalized heterocycles. It’s not uncommon for our tech team to field questions on solvent compatibility, scale-down synthesis, or methods to minimize byproduct formation during amination or reduction steps. From the agricultural side, it usually acts as a precursor to active compounds targeting certain metabolic pathways or pest species. Its robust, predictable chemistry under various lab and plant conditions keeps it in constant demand.
Small-scale chemists often want just a few grams for a reaction screen or molecular library build. This means dust control, moisture protection, and packaging in inert atmospheres—even for research-sized shipments—because even minor degradation alters results. On the other hand, commercial manufacturers expect ton-scale supply, with all the logistical planning that brings: multi-layer packaging, drum handling, and batch traceability. We maintain transparency around trace metals, color stability, and any shifts in impurity profiles as scale increases.
Our chemists review analytics after every batch—HPLC, GC, and NMR data get scrutinized beyond the minimum spec checkboxes. That’s not just to hit targets; it’s to spot patterns before they become problems. Temperature excursions during shipping might nudge assays downward or foster color changes. These ‘minor’ issues quickly escalate if overlooked. Internally, we tie each lot to a detailed process history and retain reference samples. That feedback loop lets us identify outliers fast and update process controls accordingly.
We see a lot of routine 2-cyanopyridine derivatives pass through our reactors. This one stands out because the methyl and bromo pattern doesn’t just add weight on paper. The combined electron-donating and electron-withdrawing effects make it less prone to side reactions in certain synthetic routes. Other isomers—say, a bromo at four instead of three—show less predictable reactivity. Subtle changes in substitution matter when customers attempt tricky cyclizations or Suzuki couplings; we field technical support calls when folks switch between isomers and hit roadblocks. We developed our process after fielding repeated requests for a version that minimized isomer contamination and batch-to-batch drift, which turns out to be no small feat.
Sourcing specialty fine chemicals sometimes feels like navigating a maze. A delay in critical intermediates like this one can push entire projects off schedule. We draw on robust supply contracts for our starting materials—pyridine, methyl sources, bromine—all monitored for quality. Our on-site analytical lab can respond in real-time to quality deviations. That edge doesn’t come from outsourcing or distributing another party’s product; it comes from decades of troubleshooting in our own facility, where even seasoned operators keep an eye on lot numbers and process logs.
This compound demands respect in the plant and the lab. Our operators train for careful bromine handling and waste neutralization. With a nitrile in the structure, we follow best practices for containment to prevent accidental releases. Even minor lapses—dripping from a transfer line, improper storage conditions—get logged and addressed. Moving the product safely through drums, bottles, and reactors means triple-checking seals and using proper PPE, not just relying on written protocols. Customers often ask for our input on their downstream safety questions, and we do our best to relay what we’ve learned from years of hands-on experience.
Production never stands still. Our R&D team constantly tweaks parameters—pressure, solvent choices, purification methods—to get cleaner product in higher yield. New requests sometimes push us to adopt greener bromination steps or recycle solvents. We track the impact these changes have on impurity levels, yield, and energy use. Sometimes a promising new method doesn’t scale, so we circle back, compare, and try another approach. The best practices we develop end up embedded in routine runs, not just reserved for showcase projects.
Open lines of communication with customers give us a front-row seat to the problems faced in research and production. Sometimes a distinguished research lab spots trace impurities our tests missed; sometimes a process chemist finds a storage condition that prolongs stability. We fold these lessons into our batch records and operating procedures, and our team meets often to discuss both complaints and compliments. Our improvements often start with feedback from someone who put our product through the wringer in demanding synthesis campaigns.
The fine chemicals industry takes its hit on both energy and waste fronts. Through years of production, we have worked to reduce waste solvent loads by integrating solvent recovery units on-site. Where possible, catalysts and auxiliaries are recycled, minimizing landfill-bound material. We keep detailed logs on emissions and disposal, and are pushed onward by not just regulations but our own desire to run a cleaner operation. Many of the changes in our process that cut emissions came directly from operator suggestions and front-line observations, rather than top-down edicts. We’re transparent about our progress and admit that we’re not finished yet.
No two customers use 3-bromo-6-methylpyridine-2-carbonitrile in quite the same fashion. Some run it through nickel-catalyzed amination, some through lengthy protection-deprotection sequences. We've learned to anticipate common trouble spots: incomplete couplings tracing back to a stray halide impurity, moisture sensitivity during storage, or batch-to-batch color variations which complicate purification. Sharing real-world troubleshooting tips has helped downstream users avoid wasted effort. Our technical staff often advise on solvent selections, degassing protocols, and purification tricks tailored from our own shop-floor experiences.
Change threads through the plant in subtle ways. A tweak in a supplier’s raw material profile, a substitution of a distillation column, or a new filtration aid might each nudge the product profile. We document and test each change, comparing the analytics to a long baseline of data. If an innovation causes an unexpected shift in impurity spectrum, we roll back or rework the step, guided as much by statistical process control as by the experience lodged in our staff. Routine isn’t the enemy of improvement; rather, routine provides the reference that flags unexpected deviations.
Every plant grapples with the occasional surprise. Once, a temperature probe in a key reactor drifted out of calibration. The resulting batch showed a subtle but distinct impurity pattern—one that a few customers recognized before our analytics did. Rather than sweep the batch out the door, we instituted additional checks and recalibrated all instrumentation plant-wide. The lesson stuck: real-world setbacks, more than milestones, drive meaningful process improvement in chemical manufacturing.
In recent years, disruptions in global supply lines have placed finer points on old lessons about inventory management. We run parallel supplier programs for key inputs, monitor stock levels with a dedicated team, and prioritize timely communication upstream and downstream. Customers working toward regulatory filings need extended documentation for every lot and clear assurances of uninterrupted supply. Our warehouse staff, operators, and procurement managers all pitch in to keep this vital material moving—even when overseas trade or raw material shortages threaten the schedule.
Regulatory bodies sometimes revise expectations on trace impurities or call for fresh stability data. We invest in staying ahead of new standards, not only as a compliance measure but also for the confidence it gives customers who must document every detail. When one customer’s market shifted from bulk industrial to API-grade, their requirements reset much of our batch qualification process. We have learned to roll with these cycles, drawing lessons from our own experience and from colleagues facing similar hurdles.
No amount of abstract theorizing substituting for direct plant work. The nuances of large-scale bromination, the risks involved in cyanation steps, and the subtleties introduced during final purification come through years spent walking the shop floor, not through spreadsheets. Our operators, chemists, and analysts bring this experience to bear on each lot, producing product not only by the book but by judgment honed from hundreds of runs. The difference shows in the confidence labs express when they switch from generic to our in-house sourced compound.
Chemistry never unfolds neatly. Every customer application, every scale, every set of requirements presses new demands on quality, creativity, and control. As the manufacturer, our stake in each drum and bottle runs deep, extending from raw material sourcing through final logistics. The molecule may look simple on a spec sheet, but the genuine value comes from hard-won lessons: how to nip impurity formation at source, how to streamline a process to handle larger volumes without quality trade-offs, how to troubleshoot an obscure downstream bug traced to a minor side product. Lessons learned, mistakes confronted, improvements made—these shape both our team and the future of our product.
Our experience tells us the market for specialized, reliable building blocks will only grow, placing even greater weight on sustained quality and proactive process improvement. Continuous dialogue with chemists, direct engagement with technical teams, and vigilance toward both regulatory and market forces chart the way forward. As new projects emerge and old hurdles return in new forms, we keep refining our approach, ensuring each shipment of 3-bromo-6-methylpyridine-2-carbonitrile carries with it the trust built over years of manufacturing, learning, and adapting.
