|
HS Code |
305009 |
| Chemical Name | 6-chloro-2-pyridinecarboxamide |
| Molecular Formula | C6H5ClN2O |
| Molecular Weight | 156.57 |
| Cas Number | 5277-05-0 |
| Appearance | Off-white to pale yellow solid |
| Melting Point | 167-171°C |
| Solubility In Water | Slightly soluble |
| Smiles | C1=CC(=NC(=C1Cl)C(=O)N) |
| Inchi | InChI=1S/C6H5ClN2O/c7-4-2-1-3-8-5(4)6(9)10/h1-3H,(H2,9,10) |
As an accredited 6-chloro-2-pyridinecarboxamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, screw-capped HDPE bottle labeled "6-chloro-2-pyridinecarboxamide, 25g, ≥98% purity," hazard pictograms and handling instructions printed. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 6-chloro-2-pyridinecarboxamide involves secure drum or bag packaging, maximizing space, ensuring stability, and compliance with transport regulations. |
| Shipping | 6-Chloro-2-pyridinecarboxamide is shipped in tightly sealed containers, protected from light and moisture. The package is clearly labeled with appropriate hazard information. It is transported according to standard chemical shipping regulations, ensuring proper handling to prevent leaks or contamination, and is accompanied by the necessary safety and regulatory documentation. |
| Storage | 6-Chloro-2-pyridinecarboxamide should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect it from moisture and direct sunlight. Store at room temperature, typically between 15–25°C (59–77°F). Follow standard laboratory safety procedures and refer to the Safety Data Sheet (SDS) for detailed handling and storage guidelines. |
| Shelf Life | 6-Chloro-2-pyridinecarboxamide is typically stable for at least two years when stored in a cool, dry, and dark place. |
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Purity 99%: 6-chloro-2-pyridinecarboxamide with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high-yield and consistent batch quality. Melting point 196°C: 6-chloro-2-pyridinecarboxamide with a melting point of 196°C is used in agrochemical active ingredient preparation, where it provides thermal stability during formulation. Particle size <10 μm: 6-chloro-2-pyridinecarboxamide with particle size <10 μm is used in catalyst precursor production, where it enables uniform dispersion and reactivity. Stability temperature up to 120°C: 6-chloro-2-pyridinecarboxamide stable up to 120°C is used in organic synthesis processes, where it maintains compound integrity under moderate heat. Moisture content ≤0.2%: 6-chloro-2-pyridinecarboxamide with moisture content ≤0.2% is used in custom chemical manufacturing, where it reduces unwanted hydrolytic side reactions. |
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6-chloro-2-pyridinecarboxamide stands out for its ability to deliver reliability where precision and consistency are valued. In laboratories and manufacturing floors alike, chemists rely on this compound not just for its defined functionality, but also for the confidence it brings to synthesis and development work. Anyone who has spent time surrounded by glassware and instrumentation knows how critical those factors become during a tight deadline or high-stakes experiment. I remember a project where choosing the right precursor turned out to be the most important decision over countless hours; picking a substance like 6-chloro-2-pyridinecarboxamide for its purity and reactivity helped get meaningful results instead of running into repeated setbacks.
The molecular structure brings together chlorine-substitution on the pyridine ring and a carboxamide group at just the right positions, delivering flexibility in both research and industrial environments. Chemists usually encounter the material as a fine crystalline solid, easy to handle and weigh out, sometimes even by hand depending on scale and need. Most suppliers deliver reliable purity, often over 98%. Anyone who has weighed a sample straight from the bottle knows lower impurities cut the hassle. Less time spent on purification means more time planning and testing actual experiments.
Physical characteristics fit the routines of most settings. The solid form protects against unwanted reactions in routine storage and handling. Solubility varies, but dissolving into organic solvents and performing convincingly in elevated reaction temperatures opens up many paths in synthesis, especially for folks pushing chemical space into new territory.
This compound sees action mostly in the hands of pharmaceutical and agrochemical researchers, though anyone working on advanced materials could find a place for it. A lot of new drug development relies on robust heterocycles, and 6-chloro-2-pyridinecarboxamide sits close to the heart of many lead-compound libraries. Its structure makes it a reliable stepping stone in the creation of novel molecules and active ingredients. For me, tools like this often make all the difference—especially when the research pressure is high and the need for reproducible reactions outweighs the allure of more exotic, riskier building blocks.
Beyond pharma, plant scientists and material engineers tap into its potential. The compound lets synthetic chemists add useful features to their molecules. That could mean tweaking activity, moving a property in the right direction, or even just ending frustration when cleaner intermediates are needed. The straightforward structure and reactivity mean fewer unpleasant surprises during scale-up even across different teams. Having sat through too many product-development meetings, I know the relief that comes with a starting material not causing headaches each time someone uses it.
Plenty of products try to do a similar job, but 6-chloro-2-pyridinecarboxamide brings some real advantages. First, its structural features simplify attachment points for further chemical changes. The positioning of the chlorine and carboxamide enables selective reactions that make multi-step syntheses possible. Colleagues working in med-chem often point out that a robust, predictable precursor streamlines the whole workflow and reduces fire-fighting over side reactions.
Other related chemicals might offer similar skeletons or reactivity at first glance, but subtle differences matter—a switched halogen, a methyl group off by a carbon or two, or a different core heterocycle, and suddenly the downstream chemistry turns unpredictable. If you’ve ever repeated a reaction only to have trace impurities sabotage yield, the dependability of a clean, well-characterized compound makes an immediate, practical difference.
Suppliers offer a range of pyridine derivatives, but few feature this balance: price, accessibility, manageable hazard profile, and proven performance. That speaks to the convergence of real-world constraints and the need for reliability in research-driven organizations.
Trust in a product’s origin and handling becomes even more important as research timelines shrink and regulatory scrutiny increases. Reliable sourcing, traceability, and solid data behind each batch mean less time validating each shipment and more time on strategic decisions. Based on my experience, a trusted provider can make or break a project. No research leader wants their team stuck sorting out unexpected contaminants or arguing over ambiguous certificates of analysis. Raw material quality anchors lasting progress.
Consistent batches and comprehensive documentation reflect a supplier’s respect for the work and time of researchers at the bench. Open data and transparent locations of manufacture help downstream users satisfy their own reporting demands, whether for clinical trials, environmental impact, or traceability in industry settings. The peace of mind from well-documented sourcing frees up mental space to focus on advancing actual discovery.
A compound’s accessibility shapes its uptake across industries. Hurdles like limited regional supply, uncertain logistics, or inconsistent quality can stall otherwise promising lines of research. Researchers and purchasing managers have to weigh these obstacles against timelines and project goals.
In my own journey, lags in procurement and uncertainty around purity once forced a project to stall two months—an experience far too common outside of established supply networks. Improved distribution and coordination between manufacturers and users go a long way toward bridging the gap between theory and practice.
Some markets still struggle with counterfeit or poorly characterized materials. In regions lacking reliable regulation, supply chains sometimes allow substandard product to slip through. Teams should learn from industry experiences elsewhere: prioritize reputable vendors, demand thorough documentation, and build ongoing supplier relationships that value feedback and transparency.
Better digital tracking and batch documentation can support both research and large-scale manufacturing. Blockchain and advanced database systems have started making inroads in pharmaceutical chemistry, offering greater certainty about what arrives on-site. Such improvements help laboratories keep their trust in the starting materials they depend on, reducing re-validation cycles.
Collaborative industry standards around analytical procedures, impurity profiling, and storage guidelines could further boost confidence—especially as more regulatory agencies demand comprehensive safety and environmental impact data. Many labs benefit from joining groups or consortia that set these standards, since those relationships also help guide broader industry trends.
No one working with specialty compounds like 6-chloro-2-pyridinecarboxamide expects perfection. Teams juggle dozens of practical problems—and a robust, dependable starting point supports those efforts rather than adds to the burden. I’ve sat in meetings where synthetic failures had less to do with talent or effort and more to do with unseen variables in the starting material. In those moments, suppliers who stand behind their products offer real reassurance.
Real collaboration often begins at the supply stage. Open lines of communication—feedback when something changes, quick corrections if something slips, support with safety data—help chemists at all levels focus on core innovation rather than the logistics of twice-removed batch issues.
Handling and storing 6-chloro-2-pyridinecarboxamide calls for basic good practice familiar to anyone who’s spent time at the lab bench. Standard personal protective equipment, well-ventilated spaces, and robust labeling reduce risk in day-to-day use. These routines aren’t just formalities. They represent the collective learning of countless researchers—mistakes caught early or avoided altogether.
Waste management arises as an essential part of the workflow. Labs with solid protocols for containment, safe disposal, and spill response help prevent both environmental and personal harm. Many labs already move toward greener processes, replacing solvents and streamlining reaction conditions; using a reliable, well-characterized starting material supports those goals and makes ongoing improvements more straightforward.
Chemicals like 6-chloro-2-pyridinecarboxamide occupy small but critical roles in the vast web of modern scientific effort. Every library of potential drugs, every run of performance materials, and every push to extend chemical synthesis benefits from sound choices at the ground floor.
With new technologies making it harder to hide impurities or inefficiencies, transparency and traceability have shifted from being wish-list items to outright requirements. Researchers, procurement specialists, and supply chain managers increasingly expect open data and reliable verification, a demand mirrored in more frequent supplier audits and richer documentation packages.
Some might choose different pyridine derivatives or chlorine-substituted aromatics based on price or local regulation. These choices often demand tradeoffs: lower purity, less predictable yields, and discomfort about future regulatory hurdles. For teams with tight project margins or regulatory risk, sticking with proven, well-supported products makes for easier management.
In contrast, custom-synthesized alternatives can offer flexibility in creative design but come at the cost of longer lead times, higher expense, and more complicated risk management. Based on experience, many groups find a middle ground by keeping stable commodities for day-to-day needs while experimenting with specialized reagents on smaller scales first.
To get the best out of 6-chloro-2-pyridinecarboxamide and similar materials, a few strategies go a long way. Regularly review the data that comes with each batch, especially analyzing any changes in impurity profile or documentation. This builds a habit of proactive checking, rather than reacting to downstream failures.
Regular communication between purchasing, lab staff, and suppliers helps catch bottlenecks before they disrupt progress. Sharing feedback with partners improves supply reliability and may even shape suppliers’ investment in quality systems—that dynamic shows up again and again in the chemical enterprise.
For larger organizations, investing in internal tracking systems to record lot numbers, date of receipt, and distribution to projects keeps knowledge front and center. This step not only offers a safety net for troubleshooting but also helps streamline later reporting or regulatory review.
For researchers and organizations working on tomorrow’s medical, agricultural, or material breakthroughs, dependable access to tools like 6-chloro-2-pyridinecarboxamide indirectly supports every outcome. Each project draws on thousands of such small decisions: which bottle to buy, which supplier to trust, how rigorously to check each step. All these choices build toward progress that benefits more than just one lab or company.
Keeping research moving forward means paying attention to detail—making the right call not only for today’s need, but for tomorrow’s goals as well. Choosing robust, proven, and well-documented materials turns out to be one of the simplest, most effective ways to move ahead in an increasingly complex landscape.
With innovations expanding on every front, researchers and purchasing managers keep their focus not just on price or speed, but on the cumulative value of trusted relationships and rigorous product backing. Materials like 6-chloro-2-pyridinecarboxamide might form just one link in the chain of modern discovery, yet each link strengthens the whole endeavor.
Working in research feels exhilarating and sometimes daunting. New problems and new tools surface every month. But with a strong foundation built on reliable materials, the process keeps moving. Success rests on thoughtful choices, careful vendor relationships, and staying clear-headed about what matters in the push for innovation and safety at every step.
