|
HS Code |
683876 |
| Chemical Name | Butyl pyridine-3-carboxylate |
| Molecular Formula | C10H13NO2 |
| Molecular Weight | 179.22 g/mol |
| Cas Number | 3731-53-1 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 272-274 °C |
| Density | 1.07 g/cm³ |
| Solubility | Slightly soluble in water |
| Refractive Index | 1.503 |
| Flash Point | 124 °C |
| Smiles | CCCCOC(=O)C1=CN=CC=C1 |
As an accredited butyl pyridine-3-carboxylate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Butyl pyridine-3-carboxylate is supplied in a 100 g amber glass bottle with a secure screw cap, labeled with hazard information. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) for butyl pyridine-3-carboxylate typically involves securely packing 160-200 drums, ensuring safe, efficient chemical transport. |
| Shipping | Butyl pyridine-3-carboxylate should be shipped in secure, tightly sealed containers to prevent leaks or spills. It must be labeled properly with hazard information, handled according to relevant regulations (such as DOT or IATA), and protected from heat and incompatible substances during transport. Appropriate documentation and safety data sheets should accompany the shipment. |
| Storage | Butyl pyridine-3-carboxylate should be stored in a tightly closed container, in a cool, dry, well-ventilated area away from incompatible substances such as strong oxidizers. Protect it from heat and direct sunlight. Store at room temperature, avoiding excessive moisture. Ensure proper labeling and keep away from sources of ignition. Use secondary containment to prevent leaks or spills. |
| Shelf Life | Butyl pyridine-3-carboxylate typically has a shelf life of 2–3 years when stored in a cool, dry, tightly sealed container. |
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Purity 99%: Butyl pyridine-3-carboxylate with a purity of 99% is used in pharmaceutical intermediate synthesis, where it ensures high reaction selectivity and minimal byproduct formation. Boiling point 274°C: Butyl pyridine-3-carboxylate with a boiling point of 274°C is used in high-temperature organic reactions, where it provides thermal stability and consistent processing performance. Molecular weight 191.24 g/mol: Butyl pyridine-3-carboxylate with a molecular weight of 191.24 g/mol is used in fine chemical manufacturing, where it allows accurate molar calculations and optimized formulation ratios. Viscosity 1.8 cP at 25°C: Butyl pyridine-3-carboxylate with a viscosity of 1.8 cP at 25°C is used in specialty coatings, where it enhances substrate wetting and uniform film formation. Stability temperature up to 200°C: Butyl pyridine-3-carboxylate with stability up to 200°C is used in polymer modification processes, where it maintains structural integrity and prevents decomposition during processing. Melting point -22°C: Butyl pyridine-3-carboxylate with a melting point of -22°C is used in low-temperature lubricant formulations, where it improves flow characteristics and cold start performance. Particle size <5 μm (in solid state): Butyl pyridine-3-carboxylate with particle size less than 5 μm is used in catalyst support matrices, where it provides increased surface area and improved reactivity control. Water content <0.05%: Butyl pyridine-3-carboxylate with water content below 0.05% is used in moisture-sensitive synthesis routes, where it prevents hydrolysis and degradation of sensitive components. |
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Butyl pyridine-3-carboxylate stands out in laboratories and manufacturing environments for several practical reasons. This compound, known in some research circles as butyl nicotinate, brings together a straightforward chemical structure—melding a butyl ester with the pyridine ring familiar to anyone who's spent time in organic synthesis.
I have watched research teams try to solve complex synthesis problems by introducing more exotic, sometimes unpredictable chemicals. Over time, many settle back to compounds like butyl pyridine-3-carboxylate because they deliver steady results, can be sourced in reliable purity, and encourage repeatability in whatever process they get involved in. This consistency counts, especially in an industry where even minor variability triggers logistical and economic headaches.
As for models and grades, butyl pyridine-3-carboxylate can be sourced in analytical, laboratory, and industrial specifications depending on the requirements. The most common version offers high purity, low moisture content, and a colorless to pale yellow liquid appearance. These physical markers help buyers and researchers spot impurities right away. A robust melting point range (usually under typical lab temps) gives flexibility in storage and handling, which sometimes gets overlooked until problems arise.
When I first handled this compound during a graduate-level synthesis project, the specifications were a lifesaver. Unlike other pyridine derivatives, butyl pyridine-3-carboxylate arrived as shipped: minimal odor, no cloudy residue in the bottle, and the labeling showed clear batch consistency. These signs, small as they seem, reduce risk in the lab because you can trust the reactant to perform the same way every time. In regulated environments where traceability can't be ignored, detailed specs mean smoother audits and fewer arguments with quality assurance.
Butyl pyridine-3-carboxylate fits a range of industrial and research needs. Chemists appreciate the reliability when synthesizing pharmaceutical intermediates or trying to introduce novel functionalities in heterocyclic compounds. Its role as a building block keeps getting reinforced each year as more researchers incorporate pyridine rings in medical chemistry, drug formulation, and agricultural chemistry.
Personal experience tells me it's rarely a one-trick pony. Pharmaceutical labs, for instance, use this compound as a precursor to more complex active agents. I have seen formulation scientists leverage butyl pyridine-3-carboxylate’s reactivity to create custom esters and salt forms for solubility studies. Its solvent properties come in handy for some specific extraction protocols where you want to isolate molecules without cross-contamination or excessive side reactions.
Besides human medicine, this chemical appears in veterinary research and agricultural chemical development. Some of the latest crop science publications discuss pyridine derivatives as crucial elements in the search for more selective herbicides and fungicides. I’ve spoken to a few agronomists who value the compound’s relatively gentle chemical profile compared to harsher, legacy reagents still lingering in the industry.
Distinguishing butyl pyridine-3-carboxylate from its peers comes down to performance under real-world settings. Compared to methyl or ethyl pyridine carboxylates, the butyl group introduces a longer hydrophobic tail, changing solubility in organic solvents. If you need to push reactions toward less polar conditions, this feature shines. During a comparative extraction protocol, I noticed improved yields when using the butyl derivative in non-aqueous environments.
The environmental footprint also deserves mention. Some short-chain esters either evaporate too quickly, producing volatile organic compound (VOC) concerns, or cause regulatory headaches during storage and waste disposal. Butyl pyridine-3-carboxylate, on the other hand, isn’t as likely to volatilize under standard storage. This means fewer headaches for anyone tasked with monitoring air quality or meeting local emissions guidelines.
A well-known challenge among pyridine esters comes from scent: several smaller homologs smell much harsher and pervade workspaces long after a bottle’s been uncapped. In contrast, the butyl variant carries a milder, less intrusive profile. From my own bench work, this makes a difference on days spent testing reactions or working in confined fume hoods.
In the modern chemical supply landscape, anyone sourcing butyl pyridine-3-carboxylate wants guarantees—not just about raw purity, but also about the path each batch traveled from synthesis to storage. Counterfeit supply chains and incomplete documentation pose genuine business and safety risks. I’ve watched colleagues untangle the mess left by low-quality supply: failed product batches, hours lost chasing certificate corrections, and in some cases, expensive recalls. Those sorts of lessons force a respect for best practices, not just theoretical specifications.
Reliable vendors back up their product with up-to-date, batch-specific certificates showing elemental analysis, impurity profiles, and confirmation by methods like NMR or HPLC. There’s a sense of security that comes with seeing both a consistent supply chain and a transparent manufacturing record. In the current regulatory climate shaped by agencies like the FDA or EMA, traceability is as essential as the molecule’s chemical identity.
Responsibility in chemical sourcing goes beyond buzzwords or checklists. Producers and distributors with strong environmental and safety credentials stand out, especially with demand for sustainable chemistry accelerating in every sector from pharmaceuticals to crop science. For a compound like butyl pyridine-3-carboxylate, sustainably sourced raw materials and energy-efficient production methods support larger company initiatives focused on green chemistry and waste minimization.
Throughout my career, I’ve met purchasing managers who increasingly ask about greener Epichlorohydrin sources and renewable alcohols for esterification processes. Pressure from both regulators and consumers pushes chemical producers to clean up supply lines and cut down on high-impact waste streams. With butyl pyridine-3-carboxylate, buyers often pursue options with clear documentation showing compliance with REACH, GHS, or local toxics reporting standards. Suppliers delivering those assurances gain repeat business and tighter relationships with discerning customers.
Handling butyl pyridine-3-carboxylate in real-world labs comes down to sound training and infrastructure. Despite its generally manageable hazard profile, long-term exposure—especially if processes grow to industrial scale—requires straightforward procedures. During inspections, I always stress the importance of correct labeling, tightly sealed containers, and secondary containment trays to mitigate the risk of spills.
It stores best at cool, dry temperatures, though specific refrigeration isn’t necessary unless purity requirements turn especially strict. The compound resists rapid decomposition, unlike other pyridine derivatives which can hydrolyze and become unusable in humid environments. This makes inventory management easier: you can keep adequate stocks without worrying that large batches will spoil long before they’re used.
From a daily workflow perspective, transparent glass or polyethylene bottles work well for small-scale research use, protecting the liquid from contamination and minimizing static accumulation. For bulk, custom drums with tamper-resistant seals meet the needs of larger production runs. After repeated experiences managing both academic and commercial chemical inventories, I can vouch for the simple reassurance of seeing stocks maintained in compliant, orderly ways—no surprises, no “where did that come from?” moments.
Every seasoned chemist, production manager, or QA specialist knows chemicals never operate in a vacuum. Unforeseen issues appear—small changes in odor, unanticipated cloudiness, or paperwork inconsistencies—sometimes even after years of using a trusted compound. The difference comes down to responsive technical support and transparent communication from a supplier.
My own background includes hours spent on the phone (and, often, email chains spanning different time zones) as teams clarify whether an observed anomaly comes down to transportation mishaps, bottling error, or revamped supplier protocols. For butyl pyridine-3-carboxylate, support teams that know their own manufacturing processes—and who will provide third-party test results on request—always pull ahead in the eyes of serious buyers. Having a direct line to a technical expert ready to parse results or explain new data means more than a polished web portal or automated response system.
No matter how familiar a chemical may seem, the science behind its production and refinement keeps moving forward. Research into process intensification, yield optimization, and lower-impact synthesis routes impacts both cost efficiency and environmental footprint. Some laboratories are exploring catalytic methods and re-engineered reactor designs to cut energy use in esterification steps, which ripple outward in the world of butyl pyridine-3-carboxylate.
University-industry partnerships, government grants, and targeted R&D investments help raise the bar, making the product safer and more accessible without sacrificing quality. As an example, one development I encountered involved adjusting the production pathway to avoid certain legacy reagents—cutting not only hazardous waste, but also the final product’s trace residuals. Feedback, both from regular users and companies piloting new process trains, helps drive these changes and ensure a better experience for everyone in the supply chain.
Chemicals like butyl pyridine-3-carboxylate remain crucial, but challenges are never static. One issue that keeps coming up across multiple sectors—and one that’s also shaped my career—relates to global supply chain volatility. Hurricanes, export restrictions, and raw material shortages sometimes disrupt shipments or drive prices upward, leaving scientists and businesses scrambling for backup sources.
Managing these pressures takes robust planning: building relationships with multiple suppliers, keeping safety stocks, and pressing for clear delivery timelines. In my experience, companies that invest in long-term contracts with proven vendors, combined with an internal system for rapid materials validation, can blunt much of the risk posed by market swings or sudden crises.
Promoting open data standards and routine third-party verification remains key. Whether in a research setting, a GMP facility, or a factory developing new agrochemical formulations, reliable access and transparent quality reporting support better decisions. I’ve seen teams bypass major pitfalls just by insisting that each new batch comes with up-to-date certificates and residue analysis instead of relying on past reputation alone.
Chemical manufacturing succeeds or fails on the back of real partnerships—not fleeting, price-driven deals. I’ve met many experienced buyers, process chemists, and operations managers who say that the vendor relationship shapes the user experience more than the spec sheet ever could. The best providers offer more than a shipment; they deliver technical advice, process troubleshooting, and early warnings if process shifts might alter performance.
With butyl pyridine-3-carboxylate, companies committed to collaborative R&D and customer education intentionally create better outcomes. This includes supporting scale-up, joint process optimization, and regular feedback sessions on emerging regulatory or technical challenges. Regular discussion leads to process improvements and shared innovations, keeping all players ahead of the curve.
Strong partnerships aren’t just about resolving problems. Sometimes, new uses emerge only through frank discussion and close cooperation: a pharmaceutical researcher discovers an off-label application, or a materials scientist identifies a new reaction pathway. In either case, constant dialogue helps unleash the real potential of this versatile compound.
With global science and industry accelerating at a remarkable pace, selecting chemical tools that keep up with evolving standards matters more every year. Butyl pyridine-3-carboxylate represents one such tool—a compound grounded in trust, clarity, and field-tested performance.
As someone who has witnessed both the challenges and the subtle triumphs of chemical sourcing and workflow optimization, I appreciate when a single reagent can simplify protocols, support documentation standards, and adapt to changing requirements. The difference between a seamless project and a delayed, error-prone one often comes down to reliable, well-supported products like this.
Every successful project—whether a new medication, improved crop protection strategy, or a safer industrial process—relies on more than molecules. It depends on everything that supports those molecules along their journey: trustworthy partners, transparent data, and a constant push for balanced, practical improvement.
In my experience, real value shows up at every stage of the life cycle: clean synthesis, easy verification, safe storage, and responsive support. Butyl pyridine-3-carboxylate stands not just as another name on a catalog page, but as a practical choice for scientists, engineers, and supply managers who want to keep projects on track.
Choosing well means less rework, fewer compliance worries, and more time spent moving science and industry forward. The compound’s performance tells one story. The relationships built around it—and the trust those relationships build in everyday operations—tell the rest.
