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HS Code |
987329 |
| Chemical Name | Methyl 2-chloro-6-methylpyridine-4-carboxylate |
| Molecular Formula | C8H8ClNO2 |
| Molecular Weight | 185.61 g/mol |
| Cas Number | 888504-28-7 |
| Appearance | White to off-white solid |
| Solubility | Soluble in organic solvents (such as DMSO, methanol) |
| Smiles | COC(=O)C1=CC(=NC(=C1)Cl)C |
| Inchi | InChI=1S/C8H8ClNO2/c1-5-3-6(8(11)12-2)4-10-7(5)9/h3-4H,1-2H3 |
As an accredited Methyl 2-chloro-6-methylpyridine-4-carboxylate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500g of Methyl 2-chloro-6-methylpyridine-4-carboxylate is supplied in a tightly sealed amber glass bottle with safety labeling. |
| Container Loading (20′ FCL) | Packed in 25kg fiber drums, 20′ FCL holds 360 drums (9 tons), securely palletized, moisture-protected, suitable for export. |
| Shipping | Methyl 2-chloro-6-methylpyridine-4-carboxylate should be shipped in tightly sealed containers, protected from moisture and light. It should be packed according to regulations for chemicals, with clear hazard labeling. Transport should be handled by authorized personnel, following relevant safety and environmental guidelines for storage and handling of potentially hazardous organic compounds. |
| Storage | Store **Methyl 2-chloro-6-methylpyridine-4-carboxylate** in a tightly sealed container, in a cool, dry, and well-ventilated area, away from direct sunlight and sources of ignition. Keep separate from strong oxidizing agents and acids. Ensure appropriate labeling and restrict access to authorized personnel. Recommended storage temperature is below 25°C to maintain stability. Follow all relevant safety protocols and regulations. |
| Shelf Life | Shelf life of Methyl 2-chloro-6-methylpyridine-4-carboxylate is typically 2-3 years when stored in a cool, dry place. |
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Purity 98%: Methyl 2-chloro-6-methylpyridine-4-carboxylate with 98% purity is used in pharmaceutical synthesis, where it ensures high-yield and selective active ingredient formation. Melting point 92°C: Methyl 2-chloro-6-methylpyridine-4-carboxylate with a melting point of 92°C is used in agrochemical formulation processes, where stable processing conditions are maintained. Molecular weight 199.63 g/mol: Methyl 2-chloro-6-methylpyridine-4-carboxylate with molecular weight 199.63 g/mol is used in fine chemical intermediates, where predictable reactivity in coupling reactions is delivered. Particle size <10 µm: Methyl 2-chloro-6-methylpyridine-4-carboxylate with particle size less than 10 µm is used in catalyst carrier preparation, where improved dispersion and reaction efficiency are achieved. Stability temperature up to 180°C: Methyl 2-chloro-6-methylpyridine-4-carboxylate stable up to 180°C is used in extrusion-based material synthesis, where thermal degradation is minimized. Assay ≥99%: Methyl 2-chloro-6-methylpyridine-4-carboxylate with assay ≥99% is used in analytical reference standards, where high accuracy and reproducibility in quantitative analysis are attained. Water content ≤0.5%: Methyl 2-chloro-6-methylpyridine-4-carboxylate with water content ≤0.5% is used in moisture-sensitive polymerization, where unwanted side reactions are reduced. UV absorbance (λmax 265 nm): Methyl 2-chloro-6-methylpyridine-4-carboxylate showing UV absorbance at λmax 265 nm is used in spectrophotometric detection methods, where precise quantification is enabled. Residual solvent <500 ppm: Methyl 2-chloro-6-methylpyridine-4-carboxylate with residual solvent below 500 ppm is used in electronic chemical production, where contamination risks are minimized. Color index ≤10 (APHA): Methyl 2-chloro-6-methylpyridine-4-carboxylate with color index ≤10 (APHA) is used in pigment formulation, where color purity and product appearance are improved. |
Competitive Methyl 2-chloro-6-methylpyridine-4-carboxylate prices that fit your budget—flexible terms and customized quotes for every order.
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Methyl 2-chloro-6-methylpyridine-4-carboxylate stands out in our line-up for its direct role in advanced synthesis. Every batch we turn out starts with raw materials we audit for purity the same way we watch over the rest of our output—by eye, by instrument, and by team. In practice, what lands in a customer’s drum is known by a formula, but in our workshops, it’s the result of a steady, disciplined approach. The methyl, chlorine, and carboxylate groups do not just exist in theoretical order; they matter for every transformation downstream. Our product does not float as a commodity—each run reflects the yields, conversion rates, and waste profiles we have watched across many cycles. We never let shortcuts near our reactors or our theft-proof storerooms. Every inspection builds on lessons learned from earlier cycles and feedback from our own labs.
Model designs on our site reflect choices decided after trials in reactors we have run every shift, not just from whiteboards. Careful attention has shaped the apparent color, melting point, and density; these remain consistent, respected by every returning customer who can trace their bottle’s source to our specific process. We fix these properties—not as dry numbers, but as features linked to storability, convenience in dosing, and predictable downstream results.
We make methyl 2-chloro-6-methylpyridine-4-carboxylate with one thing in mind: it performs as a building block for specialty compounds, advanced agrochemical intermediates, and often for pharmaceutical segments that demand exacting precision. Our customers put our material through conditions that punish impurities—evidence of off-grade lots shows up down the line, pushing up purification costs or, worse, sending development efforts back to square one. We have seen first-hand how a spike in color or moisture can derail a project. Reliable quality holds value above all, especially when multi-step syntheses would otherwise unravel due to a subtle shift in reactivity or the unpredictable presence of residual solvents.
Each kilogram passes check after check for the purity not just above a threshold, but consistently staying there, batch after batch. Our tech teams run analytic profiles to eliminate residual solvents that stubbornly cling to fine chemical intermediates—GC retention time, HPLC area percentages, and Karl Fisher titrations are staple routines, taught to each new chemist who joins our workflows. We celebrate every lot that passes specification because we remember every rejection and what was required to restore purpose-built quality. Color is not abstract; a yellowish tint means extra hours on a filter down the road, and one knock at our plant’s doors will show just how tightly tracked these details become once orders scale.
Comparing this specific methyl 2-chloro-6-methylpyridine-4-carboxylate to other pyridine carboxylates, we have learned that the position and types of substituents shape a product’s place in the synthesis chain. Not every chloro- or methylated pyridine yields the same outcomes in coupling or cyclization. Some similar molecules, for example, bear substitutions that dampen selectivity in follow-up transformations or spark stability issues during storage, especially if temperature swings are uncontrolled. Our molecule’s pattern—chlorine at the second position, methyl at the sixth, carboxylate at the fourth—has become known to chemists who measure downstream behavior in spectral purity and ease of functionalization.
Colleagues at partner plants often work with related esters or acids, lacking the methyl or changing the pattern of halogenation. Consistent feedback points to our grade providing a reliable handle for Suzuki, Buchwald, or Stille couplings. The reactivity difference lies in the configuration: side-by-side heating tests confirm that migrating the chloro group, for example, slows down key cross-couplings or increases the rate of unwanted byproduct formation. Sometimes, this means days shaved off an R&D project, pushing up productivity not just in visible yield, but in precious time returned to innovation teams.
We do not write theory here; applications for our product spring from years watching customers translate it into advanced molecules. Fine chemical makers typically select our ester when looking to introduce selectivity in their functional group manipulations. Some users report using it to craft intermediates for plant growth regulators or as fragments for drug molecules targeting specific enzyme families. Our scientists have heard many stories of pitfalls with poorly controlled feeds—excessive solvent residues, or isomeric impurities unreadable by casual analysis—that jam downstream columns and force wasteful reprocessing.
We keep track of how our customers integrate this molecule into their flows. Often, a careful ester group on the pyridine ring provides both protection and reactive opportunity. This lets synthetic chemists run transformations—amino substitutions, palladium-catalyzed couplings, hydrolytic cleavages—and time and again, the chosen product stands up to inert-atmosphere gloveboxes and aggressive bases that would humble weaker intermediates. The feedback we collect shows material handled with our process can be dosed directly into reactors, skipping clean-up steps that non-integrated suppliers usually recommend.
Working with regulated industry clients has taught us that documentation and traceability create just as much value as technical performance. Pharma supply chains, in particular, will not tolerate ambiguity in origin, lot genealogy, or supporting analytical data. Each consignment receives a full record, linked to sampled vials, and archived controls. Our lot IDs—not outsourced, not vague—provide direct traceability into every raw ingredient, handled safely under internal SOPs that pass demanding audits.
Across agricultural and fine chemical customers, we have learned that material consistency stems from more than the reproducibility of our reactions. Cleaning regimes, air monitoring, and batch record-keeping become routine habits due to lessons read in regulatory inspection reports and real dialog with end-users. We have adjusted small things—a switch from one filtering medium to another, for example—after reports of process fouling, never waiting for market pressure to force our hand. Continuous feedback cycles start with us, not secondhand distributors, so we update our plant protocols from the frontline, not from empty checklists.
Our sales and technical support engineers do not just quote specs or send standard files; they answer for every kink, every customer headache that stems from lot-to-lot drift or new impurity peaks. We have learned the cost—not just in dollars, but in damaged trust—of an intermediate that throws a project off schedule. Each return motivates batch review meetings, line-by-line cause analysis, and a proven cycle of course correction.
Strategies we rely on now, like real-time reaction monitoring, improved distillation control, and dedicated post-synthesis purging, all came out of this cycle of direct operator feedback. Each adjustment makes its mark on quality, letting us hand over material where risk lies only in the skill of the final user, not in our upstream work. This way, innovation does not mean increased speculation or departures from safety, but rather a tightening loop between producer and user.
All chlorinated pyridine derivatives, as we have seen, require vigilant handling. We invest in closed-system reactors, monitored venting, and trained crew. Our effluent controls and waste streams earn real scrutiny from regulatory authorities, not just the promise of future compliance. Material off-take is contained and treated, with detailed logs kept for every kilogram handled. Not every company bears this cost, but we know that short-term neglect leads to long-term pain—in stricter legal sanctions and, just as importantly, in employee health.
Over the years, we have trained new staff in direct, repetitive drills, treating every stage—charging, reaction, finishing—with the same gravity as final packaging. We know of cases in other plants, where cutting corners on ventilation or monitoring led to unwanted exposures; we talk about those openly so that each plant operator or line chemist knows the real stakes. The differences in process safety and handling discipline often spell the difference between stable supply and repeated customer disappointment.
In practice, specifications our customers expect have evolved. Ten years ago, a single number for purity sufficed; today, feedback includes requests for detailed impurity mapping, full NMR spectra, and solvent quantification below detection limits. Our own testing benches have adapted to these added layers not by out-sourcing, but by growing our own expertise and updating our panels of in-house methods. End-users express urgent demand for packing in drums or totes lined to prevent adsorption loss, which we offer after evaluating every technical and safety trade-off.
New usage patterns continue to appear. Where once our product only found its way into simple agrochemical structures, now we watch batches disappear into clinical trial supply chains, or into custom research routed for patent filings. Our adaptability here speaks less to opportunism than to our ear-to-the-ground habit—talking with researchers who need shortcuts, with plant process teams who count savings in hours, and with innovators who refuse to compromise on quality even in trial phases.
We operate as a true producer—our team sees the process start to finish, and every lot leaves with a signature from our own plant workers, not a trading partner. Plant capacity comes with discipline: we restrict batch scale-up to points where all reaction parameters have been stabilized in smaller reactors. Once new demand builds, we check not just that our final yield rises, but that side products have not snuck back in at higher throughput, nor that storage stability weakens. Customers running kiloliter-scale operations appreciate certainty, not bluster, and our record bears out as proven when side-by-side with anything imported or resold on the open market.
Remote intermediaries sometimes lose track of these core details, but as long as we manage raw materials, fractionation, atmosphere control, and every transfer phase in-house, we sleep well knowing supply risk is minimized.
What changes when a manufacturer controls every aspect of methyl 2-chloro-6-methylpyridine-4-carboxylate output? From early mistakes—batches dropped for instability, losses to uneven phase separation, recalls from poor packaging—we saw the cost of relaxing control. Tighter methods took time to master, but real payoffs started once downstream clients reported disappearing clean-up headaches and faster campaign throughput. Repeat orders do not come just from pricing games; long-term supply depends on real trust.
As competition grows, differences emerge most obviously during process scale-up or in troubleshooting a difficult synthesis. We often receive urgent calls—an unusual impurity seam shows up in a customer’s analysis, or a reaction that once worked reliably now misbehaves. Our in-house chemists pull up batch histories, run fresh tests, and can almost always pinpoint a culprit. In rare failures, we do not shy away from root cause work, and every fix is shared and added to our procedures. The value in these habits reflects years of high-pressure lessons learned not in the boardroom, but on the plant floor or at the bench.
Nobody in this business works free from mishap or change. Sometimes, shipments get delayed by customs stops or transport snarls. In these cases, we do not smugly wait things out; our team communicates, documents, and works out alternatives with users. More challenging problems—such as new regulatory demands for contaminant screening or changes in permitted uses—require rapid reading and adaptation. We devote internal resources not just to production lines but to compliance monitoring and pre-emptive audits, so we do not trip up on a regulatory surprise a year too late.
If technical issues arise for an end user—say, material sports faint decomposition on storage, or a new spectral fringe appears—our technical staff stand ready to troubleshoot, propose remedy actions, and, where needed, modify the process for subsequent lots. We run limited pilots in partnership with our most advanced users, so improvements take root quickly and benefit all downstream clients. In every change, we favor transparency—there is little value in hiding faults or hoping a hidden defect will pass unnoticed.
Every year brings new challenges. Our customers push into more sophisticated markets, and we must keep pace, updating analytics, improving yield, and cutting waste wherever possible. Green chemistry imperatives, such as solvent minimization and energy use reduction, direct our process improvements—not because mandates force us, but because we have seen their effect in reduced costs, stronger team morale, and a safer worksite. The search for biobased raw materials and improved recyclability has begun to touch our chemistry, and we test new approaches on plant scale only once lab and pilot findings prove there is no sacrifice in quality.
The technical communities using methyl 2-chloro-6-methylpyridine-4-carboxylate continue to grow and diversify. We attend industry meetings and track new patent and academic work that references our key intermediates. Feedback never slows, whether through sales, direct plant visits, or support calls logged by midnight operators. Every fresh challenge and each niche application strengthens our resolve to supply not as a distant, faceless producer, but as a partner accountable for every molecule shipped.
As direct producers, we work under the knowledge that each batch of methyl 2-chloro-6-methylpyridine-4-carboxylate, with all its carefully watched properties and performance markers, serves as much more than a line on an inventory list. Years of hands-on experience, crisis management, technical conversations, and customer troubleshooting shape every drum that leaves our floor. End users remember consistency, transparency, and rigor—not faceless bulk or empty guarantees. Our journey refines not just chemistry, but practice—and that, in the long run, defines what makes a compound like this count in the real world of advanced synthesis.
