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HS Code |
656674 |
| Chemicalname | 4-Chloro-N-Methyl-2-Pyridinecarboxamide |
| Casnumber | 220000-87-3 |
| Molecularformula | C7H7ClN2O |
| Molecularweight | 170.60 |
| Iupacname | 4-chloro-N-methylpyridine-2-carboxamide |
| Appearance | White to off-white solid |
| Solubility | Soluble in DMSO, methanol |
| Smiles | CNC(=O)C1=NC=CC(Cl)=C1 |
| Pubchemcid | 2733382 |
| Storageconditions | Store at 2-8°C, protected from light and moisture |
| Synonyms | 4-Chloro-N-methylpicolinamide |
| Hazards | May cause respiratory, skin, and eye irritation |
As an accredited 4-Chloro-N-Methyl-2-Pyridinecarboxamide 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 4-Chloro-N-Methyl-2-Pyridinecarboxamide, tightly sealed with a screw cap and safety label. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4-Chloro-N-Methyl-2-Pyridinecarboxamide ensures secure, efficient bulk shipment in sealed, standardized 20-foot containers. |
| Shipping | The shipping of 4-Chloro-N-Methyl-2-Pyridinecarboxamide requires secure packaging in tightly sealed containers, compliant with local and international chemical transport regulations. It should be protected from moisture, heat, and incompatible substances. All containers must be clearly labeled, and accompanied by a Safety Data Sheet (SDS) for handling and emergency procedures. |
| Storage | Store **4-Chloro-N-Methyl-2-Pyridinecarboxamide** in a tightly sealed container, away from incompatible substances in a cool, dry, and well-ventilated area. Protect it from moisture, direct sunlight, and sources of ignition. Label the container clearly, and store at room temperature unless otherwise specified by the manufacturer’s guidelines or safety data sheet. Ensure access is restricted to trained personnel only. |
| Shelf Life | 4-Chloro-N-Methyl-2-Pyridinecarboxamide typically has a shelf life of 2-3 years when stored in a cool, dry place. |
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Purity 99%: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with 99% purity is used in pharmaceutical intermediate synthesis, where high purity ensures consistent reaction outcomes. Melting Point 136°C: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with a melting point of 136°C is used in solid-phase synthesis, where controlled fusion properties improve process reproducibility. Molecular Weight 172.6 g/mol: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with a molecular weight of 172.6 g/mol is used in analytical reference standards, where precise molecular definition supports accurate quantification. Stability Temperature 40°C: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with a stability temperature of 40°C is used in chemical storage applications, where elevated stability minimizes decomposition risk. Particle Size <50 μm: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with particle size below 50 μm is used in fine chemical formulation, where small particles enhance dissolution rates. Water Content <0.3%: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with water content below 0.3% is used in moisture-sensitive reactions, where low hygroscopicity preserves reaction efficiency. Residual Solvents <100 ppm: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with residual solvents below 100 ppm is used in active pharmaceutical ingredient (API) synthesis, where minimal impurities protect product quality. Assay >98%: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with assay greater than 98% is used in chemical research laboratories, where high assay ensures experimental validity. Bulk Density 0.45 g/cm³: 4-Chloro-N-Methyl-2-Pyridinecarboxamide with a bulk density of 0.45 g/cm³ is used in tablet formulation, where optimal density allows uniform dosing. UV Absorbance (λmax 265 nm): 4-Chloro-N-Methyl-2-Pyridinecarboxamide with UV absorbance at λmax 265 nm is used in spectrophotometric analysis, where distinct absorbance enables precise monitoring. |
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For years, we have worked hands-on with pyridine derivatives, and every day in the plant reminds us just how valuable targeted molecular changes can be. 4-Chloro-N-Methyl-2-Pyridinecarboxamide, with its CAS number 87392-12-9, stands out in both process reliability and adaptability. We see growing demand every season, with steady orders not just from local downstream processors but also from clients scaling up custom syntheses. There’s a reason interest has grown in this molecule, and the answer isn’t just its chemical structure—it’s the way the product performs under the kind of scaled-up, repeat-use which research models often don’t reflect.
Over decades, chemists have looked for ways to improve downstream yields and cut waste in syntheses that use pyridinecarboxamide intermediates. In the early days, options were limited, and inconsistent quality slowed up whole production lines. Our team saw a chance to tackle the root problems by producing 4-Chloro-N-Methyl-2-Pyridinecarboxamide to higher, verifiable standards. By refining our process controls, improving particle filtration, and reworking our distillation management, the material coming off our line achieves a consistent, crystalline purity. These steps do more than help a datasheet look good. They make it possible for end users to count on predictability, every batch.
Within the industry, almost every research chemist or chemical engineer can recall the frustration of using a key intermediate that unexpectedly fouls up due to hidden impurities. Upstream control becomes crucial in this respect. Our lab and production teams work side by side, sharing feedback and actual batch data. This is more than theory—it’s how we actively rule out pseudo-polymorph formation or trace contamination, both known headaches for those scaling up from gram-scale to commercial production. Time and again, users report smoother conversions in subsequent reactions. Fewer surprise peaks on chromatograms. If there’s ever a surprise, it usually comes from someone trying an unproven supplier.
Each batch of 4-Chloro-N-Methyl-2-Pyridinecarboxamide leaves our factory after thorough analytical checks. HPLC purity often exceeds 99.5%. We emphasize minimizing water content and heavy metal traces to make sure downstream steps—whether nucleophilic substitution, amide coupling, or cyclization—go to completion. The crystalline powder flows cleanly, settles evenly, and resists caking, avoiding the bottlenecks seen with lower-grade material.
Our in-plant experience shows the importance of developing process adjustments that match the realities of chemical synthesis today. The specific crystalline form and melt point minimize post-reaction gumming, a notorious production snag that causes filter blockages and can reduce final yield. We’ve listened to years of feedback in pilot plants and full-scale reactors, tweaking agitation speeds and solvent balances. This hands-on knowledge isn’t something copied from a chemical manual. It’s earned on the production floor, where every slight temperature shift or trace impurity can impact results.
Compared with earlier-generation pyridinecarboxamides, this product brings a unique blend of electron-withdrawing and donating substituents. This simple but crucial structural feature supports stronger, more selective reactivity—chemists can fine-tune reaction pathways for better selectivity, higher product purity, and milder conditions. Downstream benefits in pharmaceutical and agrochemical applications are easy to spot: fewer side products, improved ease in purification, and less solvent waste.
Most users approach us with questions less about theory and more about day-to-day performance. Will the crystals clump in humid conditions? How stable is storage in sealed tanks or drums exposed to summer heat? We’ve seen shipments spend weeks in transit, yet still arrive free-flowing and uncompromised, thanks to our drying and packaging improvements.
Scale matters. Lab-scale trials don’t tell the whole story, especially when larger reactors enter the mix. Bulk handling performance, dusting concerns, and ease of transfer are the topics that arise in scale-up meetings. We’ve measured just how much the product compacts under pressure, both to verify handling through tote bins and to help engineers avoid pipeline blockages. All of these experiences feed into our process—and ultimately into the consistency our long-term customers expect.
There are plenty of pyridinecarboxamide derivatives available. Yet surprisingly small differences in structure can create big changes in downstream value. Take the 4-chloro group on our material. This halogen presence not only influences reaction pathway selectivity; it also allows for post-processing functionalizations that aren’t practical with unsubstituted or ortho/meta variants. Chemists working in pharmaceutical synthesis often look for precisely this kind of versatility.
Some competing products lack N-methylation, making them less effective in blockage reduction during certain amide-forming reactions. In our experience, the methyl group plays a key part in increasing stability during storage and suppressing side reactions under moderate temperature. Customers have shared side-by-side comparisons where our 4-Chloro-N-Methyl-2-Pyridinecarboxamide formulation demonstrated much cleaner formation of their active pharmaceutical ingredients, compared to alternatives that required additional purification steps or showed unpredictable impurity profiles.
We’re often asked about cost versus benefits. While cheaper bulk material exists, the hidden price comes through increased downtime, extra purification, and higher waste disposal. Time lost in a plant or lab because of product inconsistency can cost more than the initial savings. Repeatedly, process engineers have told us about production schedules thrown off track by using off-grade raw materials bought through unsuitable channels.
Another point—trace by-products. Many manufacturers chase high yield. We put just as much focus on minimizing unwanted side components: chloride residues, dimers, and solvent traces. Whether it’s for regulated environments such as pharmaceutical active ingredient production, or less stringently monitored agrochemical syntheses, getting batch reproducibility makes the biggest difference. It’s not fun discovering a minor impurity only after it accumulates over multiple production cycles and causes a major clean-out or even product recall. This is why real-world feedback, not just passing regulatory audits, drives our investment in process adaptation.
Our R&D team doesn’t operate in a vacuum. We engage directly with partners developing new syntheses. Through pilot quantities, we’ve supported experimental cancer therapeutics, driven crop protection compound innovation cycles, and even helped fine-tune coatings in high-demand electronics manufacturing. Many of these collaborations come directly from honest feedback—what worked, what didn’t, what must change for the next supply cycle.
Every week, we hear a new request: higher analytical standards for a biotech line, different particle size specifications for continuous flow, or alternative packaging for environmentally-controlled transport. Our process responds with agility. Over the years, continual improvements in our milling and drying technologies helped meet the tougher demands of green chemistry innovation. We’ve also invested in batch traceability, allowing users to link every delivered kilogram of 4-Chloro-N-Methyl-2-Pyridinecarboxamide to specific process data, from source materials down to final packing.
Surprisingly, many of the requests aren’t about the molecule itself, but about technical documentation, shipping flexibility, and transparent impurity profiles. Larger customers feel more secure knowing exactly what went into each batch: process logs, water content results, residual solvent analyses, and transparent COAs showing not just the minimum legal standard, but actual observed values. For the kind of high-stakes projects our material ends up in, generic documentation just doesn’t cut it.
Agile response to feedback does more than reinforce long-term business—it lifts standards for everyone. Suppliers unwilling to listen or adapt soon find themselves left behind. We thrive on conversations with chemists who want to understand not just what we supply, but how it will behave every time.
Environmental considerations have moved to the top of customers’ priority lists. Regulations and sustainability programs shape more purchasing decisions, and we meet them head-on. We know 4-Chloro-N-Methyl-2-Pyridinecarboxamide can have safety and environmental impacts if mishandled. In response, our process focuses on efficient solvent recovery, in-house recycling of by-products, and strict sourcing of raw materials for traceability and security.
Our audits meet the most current local and international standards, covering everything from worker exposure limits to control of process emissions. Routine risk assessments in our plants cover not just chemical hazards, but broader context—energy usage, water discharge, and packaging waste. We approach compliance not as a box-checking exercise, but as a continuous cycle. If a partner faces a new compliance requirement, our teams study the issue and develop scalable solutions, rather than defaulting back to old ways of working.
Customers increasingly look for proof of sustainability, usually just behind price and after-sales support. That’s honest and understandable—more efficient processes get noticed, and nobody enjoys dealing with regulatory surprises. In our experience, wins in solvent recovery, improvements in energy management, and transparent reporting all help build relationships. Each adjustment, whether in packaging material selections or disposal protocols, loops back to the product’s end-to-end value and safety.
Producing 4-Chloro-N-Methyl-2-Pyridinecarboxamide at commercial scale isn’t trouble-free. Early on, foaming in reactors created headaches, blocking in-line sensors and triggers. After months of trial, we adopted a simple mechanical adjustment to agitation speed—results improved instantly. Another lesson came from monitoring the impact of even trace amounts of process water on final purity. Introducing tighter moisture controls protected downstream steps, especially for users sensitive to hydrolysis, and highlighted the lasting value of attention to detail.
Unplanned shutdowns have a ripple effect. For every hour lost, raw material supplies pile up, finished goods can lag in quality, and partners downstream see production schedules threatened. Our operations team now runs real-time equipment monitoring and predictive maintenance cycles, prompted by past troubleshooting failures. This might sound simple but has become the foundation of predictable, high-quality runs.
There is no single formula for achieving flawless output, but what we’ve found is continual process learning shapes better chemistry over time. Each tweak—whether to solvent ratios, cooling rates, or filtration method—directly impacts what leaves our loading dock and ultimately what ends up on our customer’s bench or in their reactor. We hold regular feedback loops with clients, reviewing both successes and problems, and these sessions often spark our biggest leaps forward in capability.
As more fields adopt digital control and automation, we expect requests for custom specifications and integrated supply solutions to increase. Flexible batch sizing, just-in-time delivery, and direct digital integration with customer inventories have all become part of our daily production and delivery rhythm. We’re currently testing smart packaging that enables condition tracking throughout global shipping channels—early data suggests even longer shelf-life and easier receiving logistics for our partners.
Like many in the sector, we’re watching the development of stricter environmental regulations. Our in-house process development team works on reducing synthesis steps or finding ways to upcycle minor side-products into useful reagents, contributing not just to waste reduction, but also to cost savings and new product lines. These efforts are grounded in practical, data-driven approaches, not marketing spin. We log every incremental gain, track disposal metrics, and look for partnerships that help others in the ecosystem raise their own standards.
We see 4-Chloro-N-Methyl-2-Pyridinecarboxamide as more than a fine chemical intermediate. The way it fits into broader chemical syntheses, especially in competitive pharmaceutical and agrochemical environments, comes down to reliability. New technologies and process upgrades are coming faster each year, demanding both consistency and adaptability. From our vantage point as a manufacturer, success comes one batch at a time, with each delivery reflecting years of accumulated insight and practical know-how.
Experience on the ground has taught us that the right intermediate can save thousands in development and operating costs, increase yields, and even expand the scope of what research teams or production engineers can achieve. By focusing efforts not just on the purity number, but also on the whole chain—packaging, documentation, reproducibility, and technical support—we deliver more than a chemical. Each drum, each kilogram, is shaped by real-world problems and solutions that arise during daily production. That’s the real difference, and that’s why our 4-Chloro-N-Methyl-2-Pyridinecarboxamide remains a preferred choice for teams aiming to build new breakthroughs, and do so reliably, time after time.
