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HS Code |
793557 |
| Product Name | 2-Acetyl-5-chloropyridine |
| Cas Number | 89877-14-1 |
| Molecular Formula | C7H6ClNO |
| Molecular Weight | 155.58 |
| Appearance | Light yellow to brown liquid |
| Boiling Point | 256-258 °C |
| Purity | Typically >97% |
| Density | 1.24 g/mL at 25 °C |
| Solubility | Soluble in organic solvents (e.g. DMSO, ethanol) |
| Synonyms | 5-Chloro-2-acetylpyridine |
| Smiles | CC(=O)C1=NC=C(C=C1)Cl |
| Inchi | InChI=1S/C7H6ClNO/c1-5(10)7-3-2-6(8)4-9-7/h2-4H,1H3 |
| Refractive Index | 1.589 (predicted) |
| Flash Point | 106 °C |
As an accredited 2-Acetyl-5-chloropyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Acetyl-5-chloropyridine is supplied in a 25-gram amber glass bottle, sealed and labeled with hazard information and product details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Acetyl-5-chloropyridine: Securely packed in drums, net weight approx. 12 metric tons per 20′ FCL. |
| Shipping | 2-Acetyl-5-chloropyridine is shipped in tightly sealed containers to prevent moisture and contamination. It should be handled as a hazardous material, complying with relevant transport regulations. The chemical is typically shipped at ambient temperature, with clear labeling and documentation, and should be stored in a cool, dry, and well-ventilated area upon arrival. |
| Storage | 2-Acetyl-5-chloropyridine should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight, heat sources, and incompatible substances such as strong oxidizing agents. Store under inert atmosphere if possible. Protect from moisture and ensure proper labelling. Follow all relevant safety and regulatory guidelines for hazardous chemicals. |
| Shelf Life | **2-Acetyl-5-chloropyridine** typically has a shelf life of 2–3 years when stored in a cool, dry place, tightly sealed. |
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Purity 98%: 2-Acetyl-5-chloropyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product consistency. Melting point 69-72°C: 2-Acetyl-5-chloropyridine with a melting point of 69-72°C is used in solid dosage formulation, where it aids in controlled release properties. Stability temperature up to 120°C: 2-Acetyl-5-chloropyridine with stability temperature up to 120°C is used in high-temperature chemical processes, where it maintains structural integrity and activity. Particle size < 50 microns: 2-Acetyl-5-chloropyridine with particle size less than 50 microns is used in catalysts preparation, where it enables uniform dispersion and faster reaction kinetics. Water content ≤ 0.2%: 2-Acetyl-5-chloropyridine with water content ≤ 0.2% is used in moisture-sensitive organic syntheses, where it minimizes side reactions and increases final product purity. |
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Chemists know that finding the right intermediate can make or break a whole research project. Years of navigating the world of fine chemicals have shown that minor shifts in a molecule’s structure can open new doors or block trusted paths. Anyone looking for reliability and versatility often finds themselves considering pyridine derivatives. The structure of 2-Acetyl-5-chloropyridine lands right in that sweet spot where reactivity and selectivity work side by side, and it’s worth talking about how this specific compound changes the game for researchers and manufacturers alike.
In labs and on the production floor, people want tools that don’t waste their time or resources. 2-Acetyl-5-chloropyridine brings both chemical flexibility and a strong, reliable performance. It stands out among pyridine derivatives not just because of its well-placed chlorine and acetyl groups, but because of its clear contribution to building more complex molecules. It is one of those rare compounds that supports new ideas instead of forcing users into well-trodden routines.
To understand what sets 2-Acetyl-5-chloropyridine apart, let’s start with its chemistry. The pyridine ring structure is a go-to for anybody in medicinal chemistry or agrochemical synthesis. Here, we see an acetyl group on the second position and a chlorine atom on the fifth. That arrangement shapes both the reactivity profile and the range of places the compound fits into. The acetyl group brings a familiar set of carbonyl chemistry reactions, letting the molecule serve as an anchor or a transporter for further molecular changes. The fifth-position chlorine atoms have a talent for selective substitutions, offering a way to go after specific targets in downstream reactions.
You might think, “A pyridine is a pyridine,” but those who’ve compared various derivatives know the fine details matter. For instance, swapping halogens or shifting functional groups around the ring can turn a highly reactive intermediate into a dead end. This compound brings balance – its specific substitution pattern keeps it stable enough for storage and transport, but ready for action when needed. In projects where time, stability, and flexibility carry equal weight, it provides a workable answer instead of extra hurdles.
Over the years, I’ve watched producers of pharmaceuticals and crop protection chemicals move away from broad, wasteful syntheses toward clean, specific processes. 2-Acetyl-5-chloropyridine comes up again and again in routes where a carefully controlled reaction means less byproduct and better yields. In medicinal chemistry, for example, it delivers both the backbone and the functionalization possibilities for constructing small molecules. Synthetic routes for certain antifungals or selective kinase inhibitors put this compound front and center.
Its popularity isn’t just because it’s “another intermediate.” There are times when lab results hinge on getting a chloropyridine at the right step, with the acetyl group offering a hook for further work. Those who’ve built up analog libraries from a common starting point recognize how little changes in the intermediate can have a dramatic effect on final results. Academic labs, too, lean on this compound for exploratory synthesis. The chemistry textbooks don’t always reflect how often researchers turn to 2-Acetyl-5-chloropyridine in their toolbox – a detail that regularly emerges in peer-to-peer discussions and organic synthesis workshops.
It isn’t just about high-profile drug candidates or active agrichemicals. 2-Acetyl-5-chloropyridine supports the development of dyes, imaging agents, corrosion inhibitors, and even some flavor and fragrance applications where trace-level pyridine structures shift the properties of the final blend. The versatility here means users can get creative, deploying it across a spectrum of fields instead of pigeonholing the molecule as a niche product.
Fancy packaging and marketing terms have never manufactured a chemical that solves real-world problems. I’ve seen chemists burn through their budgets chasing the latest derivative, only to realize that an “improved” substitute added steps and reduced margins. The reputation of 2-Acetyl-5-chloropyridine rests not on promises but on years of reliable performance. People remember the projects that worked – not the press release, but the reaction that gave an 80% yield without forcing a redesign or blowing out the waste stream.
Researchers and production leads discuss purity more than price tags, because process interruptions and regulatory headaches cost far more in the long run. Commercial versions of 2-Acetyl-5-chloropyridine are available in several purity grades, making them accessible for both early discovery work and full-scale production runs. Routine spectral data and tight impurity profiles matter in real-world settings, especially now, as end users and regulators demand traceability and data transparency.
Pyridine chemistry is crowded, with dozens of derivatives flooding catalogs every year. The distinction between a well-chosen intermediate and an awkward workaround often comes down to selectivity. Comparing 2-Acetyl-5-chloropyridine with relatives like 2-acetylpyridine or 5-chloropyridine, it stands out for its dual-reactive nature. You get the benefits of both an electron-withdrawing acetyl and a chlorine site susceptible to cross-coupling or nucleophilic attack.
Some molecules in this class either go too far, introducing so much reactivity that storage gets risky, or too little – locking themselves out of the reaction conditions most research teams use day to day. The sweet spot 2-Acetyl-5-chloropyridine occupies simplifies synthesis, minimizes side products, and handles a broader range of conditions. Lab staff who have compared yields and selectivity data know that cutting down on purification steps and improving scale-up rates brings real economic value. In my own experience, shifting to this intermediate cut days off a project deadline, both by speeding up chromatography and reducing failed experiments.
Another feature that people sometimes overlook: scalability. Some pyridine building blocks might look great for a 200 mg proof-of-concept, but they become nightmares for multi-kilo preparations. Thermal and chemical stability in 2-Acetyl-5-chloropyridine means fewer surprises, less downtime, and repeatable batch quality. The practical result is consistency. In manufacturing, that translates directly into fewer recalls, less off-spec material, and more confident regulators.
Long before “green chemistry” became a buzzword, people in the industry were already thinking about solvents, waste, and exposure risks. Using 2-Acetyl-5-chloropyridine doesn’t require elaborate handling procedures. That’s not just a convenience – it adds up in keeping workplace incidents down and ensuring compliance with safety standards. All chemicals need careful handling, but experience shows that those with well-understood hazard profiles and moderate volatility get through audits and inspections with fewer problems.
From a sustainability angle, the ability to use this molecule in high-yielding reactions means less waste. Years ago, few production teams factored atom economy into their purchasing decisions, but now this thinking guides nearly every major industrial investment. Transparent supply chains and documented provenance matter to everyone from purchasing agents to chief compliance officers. Companies are pushing suppliers to provide not only purity certificates, but also evidence of responsible manufacturing practices.
Safer alternatives to older, more hazardous intermediates are gaining ground. The fact that 2-Acetyl-5-chloropyridine often replaces multi-step sequences involving more reactive chlorinating agents or environmentally persistent materials makes it easier for procurement and R&D teams to justify the switch. Having worked on projects where environmental audits delayed product launches for months, I can say – with conviction – that real-world compatibility with modern environmental regulations is no small thing.
Users often need to know what actually makes one batch of 2-Acetyl-5-chloropyridine better than another. There’s a world of difference between a technical grade for early trial work and a refined lot for good manufacturing practice environments. In my lab days, we learned fast that lightly characterized intermediates could torpedo an entire project through unknown impurities. Reliable suppliers typically provide this compound as a crystalline solid, which makes handling more predictable. Most batches come with melting point data, NMR characterization, and GC or HPLC purity assessments, rather than only weight percentage.
Filtering through competing products, one difference stands out: robust reproducibility. Feedback from peers in process development regularly comes back to purity and performance consistency. Having a supplier able to promise and deliver a single-digit PPM impurity profile reduces analytical work for every downstream step. Teams get to spend time driving innovation instead of troubleshooting unexpected peaks on a chromatogram. Whether it’s a pilot plant or a university research group, that edge becomes critical.
As global markets put more strain on the fine chemical supply chain, flexibility and reliability aren’t just buzzwords – they keep operations running. End users report feeling more secure going into late-stage development with intermediates like 2-Acetyl-5-chloropyridine, where small variations don’t upend entire projects. Unlike some niche reagents, supplies for this compound have held steady even through recent turbulence in global logistics.
Most companies don’t publicize internal crises where a lost shipment or late material release derailed a key milestone. Many chemists have stories about being forced to improvise with inferior starting points after a core intermediate was delayed or backordered. Knowing that 2-Acetyl-5-chloropyridine is available through established supply channels has become a real asset for both large organizations and resource-strapped startups. Being able to focus on problem solving, rather than scrambling for alternatives, marks the difference between successful launches and missed opportunities.
Of course, no compound is perfect. Some find the need to control moisture more closely than with fully protected derivatives, especially if working at scale. Temperature management during storage and transport deserves real attention, mainly to prevent product degradation over long periods. These are known quantities – not mysterious stumbling blocks – and they’re manageable through practical protocols. Over time, these issues usually become part of the accepted rhythm of production, similar to precautions taken for a thousand other lab essentials.
Feedback from seasoned users sometimes points to variability in supply chain purity, especially if jumping between vendors or regions. The solution lies in transparent communication, cross-testing between lots before final purchases, and contract arrangements that specifically reference agreed analytical standards. Active engagement with suppliers helps nip any hiccups in the bud, turning a potential headache into a routine quality check instead of a crisis.
At a time when global industries are competing on efficiency, speed, and environmental soundness, the puzzle of what raw materials to trust takes on fresh urgency. Choosing 2-Acetyl-5-chloropyridine is less about jumping on a trend and more about trusting a compound that supports innovation and reliability. The stories and hard-won lessons from the lab bench and the production line alike echo a clear message: simplicity and reliability often do more for progress than bold promises or short-term cost savings.
The shift in industry – from blockbusters to precision manufacturing, from broad-spectrum syntheses to tailored targets – demands a rethinking of what counts as valuable. The continuing relevance and success of 2-Acetyl-5-chloropyridine point to its quiet strength. Unlike headline-grabbing products, it does its work as a foundation rather than a showpiece. Whether building a new molecular scaffold, scaling up a novel drug lead, or supporting green chemistry goals, this compound provides confidence at every step.
Regulatory pressures, rising raw material costs, and shifting customer expectations have made trust a rare commodity in today’s chemical markets. Reliable performance – proven over years and across continents – is no longer negotiable. People lean on proven intermediates like 2-Acetyl-5-chloropyridine not because of flashy marketing, but because there’s enough shared experience to know what it delivers.
Looking around at how teams now make purchasing decisions, one thing stands out. The emphasis falls less on price sheets and more on robust, reproducible results. Scientists and procurement leads are quick to talk up the value of well-documented, straight-shooting intermediates. In my work supporting project teams, switching to 2-Acetyl-5-chloropyridine rarely gets a line in the press release. But over the course of a long product cycle, it earns a steady reputation as a problem-solver, not a troublemaker.
Success with any compound demands more than just a label and a shipment. Clear documentation, technical support, and ongoing feedback keep projects on the rails. Whether a user faces novel formulation challenges, custom scale-up requests, or rigorous regulatory review, working with suppliers who speak the same technical language smooths the whole process. For 2-Acetyl-5-chloropyridine, the established body of literature and its strong support network among scientific suppliers reduce startup pains and late-stage surprises.
Making the transition from a small batch to full production often uncovers the little gaps that slow entire development cycles. Those navigating regulatory testing, environmental filings, or international patents know the peace of mind that comes from standardized data and prompt support. This isn’t about chasing the next shiny thing – it’s about finishing the work and knowing the water won’t run muddy a year or two in.
The history of chemistry is full of discoveries that promised much but fizzled after a few years. 2-Acetyl-5-chloropyridine never fit that pattern. Its presence in catalogs and research reports reflects an enduring value – not because it does everything, but because it does so many things so well that chemists can trust it for the unexpected. Whether you’re building out a small lab project or piecing together a multinational manufacturing campaign, this molecule stands ready.
The search for better, simpler, and more effective chemical intermediates continues. Experience says that 2-Acetyl-5-chloropyridine offers a dependable, flexible tool. For those who care deeply about quality, reliability, and results that don’t come with tradeoffs, it remains a sensible choice at the heart of modern synthesis.
