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HS Code |
969165 |
| Chemical Name | 2-chloro-5-ethylaminomethylpyridine |
| Molecular Formula | C8H11ClN2 |
| Molecular Weight | 170.64 g/mol |
| Cas Number | 1340478-22-7 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | Approximately 260 °C (estimated) |
| Solubility | Soluble in organic solvents like ethanol and DMSO |
| Purity | Typically ≥98% |
| Density | Approx. 1.12 g/cm³ (estimated) |
| Storage Conditions | Store at 2-8°C, keep container tightly closed |
| Smiles | CCNCC1=CN=C(C=C1)Cl |
| Flash Point | Approx. 120 °C (estimated) |
As an accredited 2-chloro-5-ethylaminomethylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, 100 grams, sealed with a screw cap. Label includes chemical name, hazard symbols, batch number, and manufacturer information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 14 metric tons (MT) net weight, securely packed in drums or IBCs for international shipment of 2-chloro-5-ethylaminomethylpyridine. |
| Shipping | 2-Chloro-5-ethylaminomethylpyridine is shipped in tightly sealed, chemical-resistant containers to prevent leaks and contamination. It should be transported according to all applicable regulations for hazardous chemicals, protected from heat, moisture, and direct sunlight. Shipping documentation includes safety data sheets and appropriate hazard labeling to ensure safe handling and compliance. |
| Storage | Store 2-chloro-5-ethylaminomethylpyridine in a tightly sealed container, placed in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers and acids. Protect from direct sunlight and moisture. Clearly label the container, and ensure access is restricted to trained personnel. Use appropriate chemical storage cabinets if available and check for leaks regularly. |
| Shelf Life | **Shelf Life:** 2-chloro-5-ethylaminomethylpyridine is stable for at least 2 years when stored cool, dry, tightly sealed, and away from light. |
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Purity 98%: 2-chloro-5-ethylaminomethylpyridine with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and batch consistency. Molecular weight 170.64 g/mol: 2-chloro-5-ethylaminomethylpyridine with a molecular weight of 170.64 g/mol is used in agrochemical formulation, where it enables precise dose calculations for active ingredient delivery. Melting point 92°C: 2-chloro-5-ethylaminomethylpyridine with a melting point of 92°C is used in specialty catalyst development, where it provides thermal process stability. Particle size ≤50 μm: 2-chloro-5-ethylaminomethylpyridine at particle size ≤50 μm is used in fine chemical blending, where it delivers uniform dispersion in solid mixtures. Stability temperature up to 120°C: 2-chloro-5-ethylaminomethylpyridine stable up to 120°C is used in high-temperature resin modification, where it assures chemical integrity under processing conditions. Water content <0.2%: 2-chloro-5-ethylaminomethylpyridine with water content below 0.2% is used in moisture-sensitive reactions, where it prevents hydrolysis and preserves product efficacy. Refractive index n20/D 1.567: 2-chloro-5-ethylaminomethylpyridine with refractive index n20/D 1.567 is used in optical material research, where it enhances refractive properties in composite materials. |
Competitive 2-chloro-5-ethylaminomethylpyridine prices that fit your budget—flexible terms and customized quotes for every order.
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In the world of fine chemical manufacturing, clarity matters more than broad claims. Our experience producing 2-chloro-5-ethylaminomethylpyridine has shown us just how much careful control and consistent engineering translate to value for innovators working with pyridine derivatives. If you ask any chemist with years behind the bench, they’ll tell you that even small variations in raw materials ripple through a synthesis, affecting purity, reproducibility, and yield. That’s exactly why we’ve tailored our process for this compound—from starting materials to final purification—around the needs of specialists who don’t settle for assumption.
Our 2-chloro-5-ethylaminomethylpyridine carries a precise structure: a pyridine ring chlorinated at the 2-position and substituted at the 5-position with an ethylaminomethyl side chain. The identity of each batch comes supported by NMR and HPLC analyses, which we share with customers, not just mention in passing. We’ve refined the handling of moisture and trace impurities, key factors that show their impact in route scouting or process scale-up, where unwanted byproducts can cost more than time.
Producers like us live by returns: not just financial, but process feedback. From our own work, instability in substituted pyridines often comes from incomplete removal of precursors or side-products. We prioritize robust control from reaction to purification. Ours is an environment where every operator, chemist, and quality analyst is close to the product, and any deviation pops up swiftly in batch records and analytics. We draw lessons from every outlier, and use that to tweak protocols—whether by choosing a different ratio of reagents, extending drying, or tightening ambient humidity limits in the packing area.
Unlike traders or distributors, we see the details others ignore. If you walk our plant, you’ll see every drum, every label, and the faces behind each lot. This proximity means our teams catch challenges that desktop purchasers might never notice. They know that if a customer’s polymerization fails, if a bioactive lead candidate goes off-spec, errors often trace back to trace contamination or mislabeling earlier in the supply chain. So our production values show in every milliliter we send out.
Our product finds regular application as an intermediate for agrochemical active ingredients, specialty coatings, and pharmaceutical research. Its performance as a versatile synthetic node comes not just from its reactive profile, but from the stability and clean reactivity ensured during its production. Chemists choosing this intermediate often face pressure on multiple fronts—safety, cost, step economy. We keep our doors open to their feedback, learning what works where, and why choices at the chemical level compound throughout their research or factory floor operations.
Over the years, our customers share that using a consistently pure batch of this compound shaves days off post-synthetic purification, reduces chromatography cycles, and avoids batch rejections. This reduces solvent consumption—a hidden but real operational cost for most modern labs and plants. Our formula respects both time and resources, shrinking environmental impact with direct consequences on the ground.
The spectrum of aminomethyl-substituted pyridines stretches wide—with differences emerging not just in substitutions, but in the trace profiles that stem from synthetic routes. Some manufacturers batch-produce multiple related derivatives in single suites, leading to cross-contamination or trace adulteration. We take another route. We dedicate reactors for critical steps and validate cleaning cycles using real analytical data, not just SOP checklists.
Compared to 2-methyl- or 3-chloro- derivatives, our 2-chloro-5-ethylaminomethylpyridine holds its ground for targeted applications where nucleophilic aromatic substitution reactivity from the chloro substituent and solubility from the ethylaminomethyl group get harnessed together. Feedback from scale-up chemists shows that side reactions drop when starting from a clean profile—there’s less need for multiple extractions or lengthy reslurries. Instead of margin-boosting shortcuts with incomplete intermediates, we invest in thorough in-process testing, confirming batch identity before and after each purification.
Every lab and factory works with deadlines: the reality of hits and misses, efficiency and hemmed budgets. Chemical synthesis rarely rewards doing the bare minimum. Working with this product since its early process routes, our team identifies failure modes before they become expensive. Perhaps the crude intermediate shows a persistent pink tint—an oxidation byproduct most visible in pyridine derivatives. We trap and remove these stages, learning from both the data and the story behind the impurity spike. This way, every kilo we deliver isn’t just a number on a manifest; it carries forward the lessons of every earlier shipment.
Our familiarity with field reports tells us that the flow of information between producer and end user cannot rely on bullet points. Sometimes, a customer needs faster dissolution for an automated reagent dispenser, or lower halide ion carryover to protect delicate downstream catalysts. Instead of resting on a technical data sheet, our technical support team walks through analytical methods, sample retesting, and shares honest observations about material handling during storage or transport. Across hundreds of batches, we log, analyze, and share not only yields but also time-on-task, energy consumption, and head-space gas chromatograms to spot emerging trends.
In the age of regulatory scrutiny and environmental awareness, we have learned not to separate compliance from craft. Our audits run close to daily life, with process records and waste handling visibly tracked through electronic logs that production teams see in real time. If a discrepancy crops up, it doesn’t pass through layers of abstraction before corrective action kicks in. This culture strengthens not only trust in the batch quality, but builds a credible track record our partners value during their own registration and quality assurance audits.
We benchmark environmental controls, applying best practices from our lessons in solvent recovery and emission abatement. Our dedicated QA staff takes lessons from every event—whether a filtration hiccup or a vessel cleaning record—and folds it into the system so repeating errors shrink batch by batch. If the industry ever expects to build safer, greener pathways to specialty chemicals, manufacturers can’t just talk up their standards from boardrooms; the belief must seep through daily routines.
Our small-team approach helps us recognize the actual impact of consistent performance in 2-chloro-5-ethylaminomethylpyridine for large-scale campaigns. As demand for API intermediates or advanced specialty chemicals climbs, nothing erodes supply chain confidence more than unplanned delays caused by non-conforming materials. Our “recertification” culture means product isn’t shipped until both legacy analytical criteria and new customer-driven parameters match. New regulatory concerns or analytical requirements get addressed promptly, and we document every experiment to support scale-up or process transfer, not just internal development.
Colleagues from various industries have pointed out that even subtle changes—a slightly longer drying cycle, a switch in a supplier’s ethanol—can cascade into end-use issues: incomplete reactions, off-flavors in flavor intermediates, or stuck fermentations in biotech projects. Each learning cycle with these problems improves our technical documentation and adds resolution to every subsequent batch release. This feedback loop between operator, chemist, and end user shapes not just how we run our plant, but also the ongoing support we offer along the project lifecycle.
Lab and plant teams using our product report steady handling properties and minimal batch-to-batch adjustments in their recipes. Because the compound stays free-flowing and stable in long-term storage—once kept away from excess moisture and light—plants handling large-scale volumes don’t lose material to caking or degradation. Sampling on arrival aligns with our own retained reference samples, slicing dispute time in half if discrepancies pop up in downstream analytical testing.
Users working in flow chemistry, medicinal chemistry, or discovery projects have mentioned that the combination of purity and real-time support from our technical team shortens troubleshooting compared to large, distant suppliers. We avoid generic advice and respond with case-specific input, incorporating everything from solubility behavior in different solvents, to observations on color during reaction sequences, or early warnings about incompatible metals in downstream equipment.
Every change in process, raw material source, or analytical standard needs documentation and hands-on adjustments. Our production protocols for 2-chloro-5-ethylaminomethylpyridine balance throughput with control, so even as we scale, we don’t lose sight of the reason our customers return: results that reduce noise in their own operations. Our process engineers and shift leaders—who have grown with the plant since its startup—spot bottlenecks and teach new staff how to recognize “normal” versus “action needed.”
Staff turnover, new regulatory oversight, and process audits all carve their lessons into our workflows. Instead of resisting new requirements, we collect feedback from site visits, batch documentation, and problem tickets to write improvements into the next set of work instructions and batch records. Our goal extends beyond a warehouse full of product: our mission builds lasting reputations, not just quick transactions.
The demands in pharmaceutical or specialty chemical synthesis have never been higher. Project timelines shrink, customer expectations stretch, and cross-regional supply chains add complexity beyond what any textbook could anticipate. Over years of supporting R&D, scale-up, and tech transfer, we have embedded direct communications between our process chemists and project managers and those on the customer side. This kind of engagement prevents misunderstanding and speeds up creative troubleshooting.
Sometimes, users ask for unusual sample cuts—less common solvents, dry ice packaging, or custom labeling for traceability in pilot plant installations. Our capability comes from lines of communication that run both ways: a scientist in Europe’s synthetic lab, for example, reaches out about a lot’s identity, and we don’t respond with jargon, but with a direct walk-through of the batch history, analytical files, and logistics choices.
Direct feedback leads us to incorporate further process tweaks, whether shorter vacuum drying, or the adoption of faster non-aqueous workups to reduce salt load in the finished product. Over time, this cooperative model means innovation doesn’t just happen at the user’s bench, but in our production hall as well. These collaborations set our standard for supporting not just routine deliveries, but the unexpected turns that advanced chemistry throws at us all.
It’s easy to treat intermediates as simple commodities—replaceable, interchangeable. Our experience delivering 2-chloro-5-ethylaminomethylpyridine proves the exact opposite. Traceability down to raw material batches and operator logs saves more than regulatory headaches; it pulls real weight if a plant needs to track a question back through weeks or months of production.
We maintain long records—digital and physical—for each production run, tying every output container to a synthesis lot, an operator, and the specific time and conditions in which it was produced. This kind of tracking offers reassurance in case of unexpected process events, reanalysis, or documentation for regulatory filings and product registrations. If a regulatory body requests lot-specific data, we respond not with generalities but with PDFs of real spectra, process step logs, and full batch records.
Every industry cycle brings new challenges. Price swings in chlorinated feedstocks, regulatory changes on process emissions, and shifts in downstream demand force us to adapt, not just react. We ride out tight feedstock supplies by securing advance contracts, holding safety stock, and reevaluating solvent recycling strategies before a shortage bites. This stability lets our customers avoid last-minute scrambling for alternatives in their own syntheses.
Not every problem comes solved overnight. Unplanned downtime, power outages, or surprise customer requirements have all found us on night and weekend shifts hunting for root causes. One lesson repeats across these events: open communication and willingness to share our process experience always pay off. Our plant manager, who’s walked every production area, sits regularly with lab analysts and logistics planners to discuss “what went right” and “what slowed us down.” This reflection, sometimes informal over coffee but always direct, shapes the improvements in both our product consistency and our support.
Producing 2-chloro-5-ethylaminomethylpyridine means more than mixing chemicals and shipping containers. The work draws together years of technical learning, hands-on trial, and the discipline to turn every setback into a concrete change on the shop floor. We don’t operate at arm’s length; we meet our peers in research labs and manufacturing teams as equals who know the stakes.
Across thousands of kilos and countless production hours, our method remains—invite scrutiny, share experience, and deliver exactly what’s promised. This approach means fewer surprises, less downstream troubleshooting, and more shared satisfaction when new molecules reach the market or process bottlenecks disappear. Our team produces and supports this compound not only to fill an order, but to empower the next advances in science and industry—for customers who value real, unfiltered expertise.
