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HS Code |
804696 |
| Name | 3-Acetyl-2-isopropylpyridine |
| Cas Number | 935-30-0 |
| Molecular Formula | C10H13NO |
| Molecular Weight | 163.22 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 255-257°C |
| Density | 1.03 g/cm3 |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Smiles | CC(=O)C1=CN=C(C(C)C)C=C1 |
| Iupac Name | 1-(2-isopropylpyridin-3-yl)ethanone |
| Refractive Index | 1.521 |
| Flash Point | 108°C |
As an accredited 3-Acetyl-2-isopropylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle, tightly sealed, labeled "3-Acetyl-2-isopropylpyridine," with hazard symbols and batch information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Acetyl-2-isopropylpyridine ensures safe, efficient bulk transport with secure packaging to prevent contamination or leakage. |
| Shipping | 3-Acetyl-2-isopropylpyridine is shipped in tightly sealed containers to prevent contamination and loss. It should be stored and transported at room temperature, away from direct sunlight, heat, and incompatible substances. Standard chemical handling and shipping regulations apply, with proper labeling and documentation to ensure safe and compliant delivery. |
| Storage | **3-Acetyl-2-isopropylpyridine** should be stored in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizing agents. The container must be tightly sealed when not in use to prevent moisture and contamination. Use amber or opaque containers to protect from light, and ensure proper chemical labeling for safety and compliance. |
| Shelf Life | 3-Acetyl-2-isopropylpyridine typically has a shelf life of 2-3 years when stored in a cool, dry, tightly sealed container. |
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Purity 99%: 3-Acetyl-2-isopropylpyridine with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high batch-to-batch consistency and product yield. Melting point 68°C: 3-Acetyl-2-isopropylpyridine with a melting point of 68°C is used in agrochemical formulation processes, where it permits precise temperature control during compound crystallization. Molecular weight 177.24 g/mol: 3-Acetyl-2-isopropylpyridine with a molecular weight of 177.24 g/mol is used in chemical research analytics, where it enables accurate stoichiometric calculations in reaction design. Stability temperature up to 120°C: 3-Acetyl-2-isopropylpyridine with stability temperature up to 120°C is used in catalyst development, where it maintains structural integrity under elevated reaction conditions. Low water content (<0.2%): 3-Acetyl-2-isopropylpyridine with low water content (<0.2%) is used in electronic material manufacturing, where it minimizes hydrolytic degradation and improves final product quality. |
Competitive 3-Acetyl-2-isopropylpyridine prices that fit your budget—flexible terms and customized quotes for every order.
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In any laboratory setting, reliable chemical compounds shape the progress of both basic research and industrial development. 3-Acetyl-2-isopropylpyridine stands out as more than a mouthful of a name. This compound holds its own in a demanding field where consistency, purity levels, and traceability matter every day. Having spent years sorting through all kinds of chemicals while working shoulder to shoulder with researchers and application specialists, I have come to appreciate why it matters to look beyond just “what is it” toward how a compound like this can genuinely make a difference.
There are thousands of pyridine derivatives on the market, but not all hit the bar for rigorous analytical, research, or pharmaceutical work. 3-Acetyl-2-isopropylpyridine’s chemical fingerprint—a pyridine ring with both an acetyl and an isopropyl group—doesn’t only define its molecular structure. That unique combination gives it physicochemical characteristics that can push innovation forward in flavor chemistry, organic synthesis, and even in fields like material science. Over repeated cycles of acquisition and use, my preference always leans toward products supported by transparent sourcing records and up-to-date Certificates of Analysis.
While working closely with scientists and procurement teams, I’ve noticed that actual impact comes down to consistent batch quality, reliable purity grades, and access to impurity profiles. For the 3-Acetyl-2-isopropylpyridine that sees real-world use, top suppliers provide specifications with clear assay percentages (often greater than 97% or 98% for research grade), low moisture content, and well-documented chemical safety profiles. Those particulars aren’t just technical demands—they ensure smooth, reproducible outcomes in both recipe formulation and scaling up from lab to pilot production.
People often see long chemical names and tune out, imagining rare or boutique uses. Over the years, my own experience shows 3-Acetyl-2-isopropylpyridine’s importance cuts across more than one field. It pops up in pharmaceutical research as a useful building block in heterocyclic chemistry. Its structure provides a versatile handle for further modification, something synthetic chemists value in drug discovery or lead optimization. In the hands of flavorists and fragrance designers, it adds finesse—subtle, tobacco-like notes or nuanced top notes, depending on the application, thanks to its aromatic profile.
Food and beverage science doesn’t shy away from specific, trace-level molecules either. Analytical chemists track pyridine-derived compounds like this to understand flavor development in roasting or aging. Those seeking to replicate or enhance naturally occurring aroma profiles use compounds like 3-Acetyl-2-isopropylpyridine in microgram concentrations. Maintaining clarity about food-grade compliance and toxicity benchmarks sets better suppliers apart, especially when compounds walk the line between experimental and commercial.
Anyone who has handled pyridine or its simple cousins knows that structure changes function. The addition of both an acetyl and an isopropyl group to the ring alters volatility, solubility, and even how the molecule participates in downstream reactions. This matters, since standard pyridine is notoriously pungent and often overshadowed by its basicity and solvent behavior. 3-Acetyl-2-isopropylpyridine brings a more nuanced aroma and a different solvation footprint to the lab bench, which opens up flexibility in formulation design as well as potential new routes in organic synthesis.
Unlike simpler pyridine analogs that play supporting roles as solvents or base reagents, substituted variants like this one actually step into the spotlight as reactive partners or precursors for more complex chemical targets. That might sound like a minor point, but in pharmaceutical lead generation or catalyst design, a fresh functional handle can save weeks of failed experiments. In my experience, shifting from bare-bones pyridine to a selectively substituted derivative introduces opportunities for regioselective or stereospecific modifications, helping cut down on purification headaches that plague later stages of development.
Year after year, textbook properties only take you so far. What matters to industrial or academic labs is how a chemical behaves during transfer, storage, and reaction set-up. The physical stability of 3-Acetyl-2-isopropylpyridine means less hassle with degradation or unexpected byproduct formation. A boiling point comfortably above room temperature, satisfactory solubility in a broad range of organic solvents, and limited water absorption serve up repeatable performance. My own notebooks have more than a few entries noting ease of weighing and transfer, which is never guaranteed with stickier, more hygroscopic analogs.
Comparing samples from different vendors, I’ve noticed visible differences: clear, low-coloration liquid as a sign of low impurity loading, tightly sealed bottles that resist evaporation, and precise batch tracking that makes sourcing replacement material less of a scavenger hunt. This experience speaks directly to research timelines and budgets: a poorly packaged or poorly documented batch invites delays and uncertainty, especially at critical stages of a multicenter project or commercial method validation.
With any specialty chemical, safety can never become an afterthought. Good practice depends on accurate Safety Data Sheets, clear labeling, and an honest accounting of storage or disposal considerations. 3-Acetyl-2-isopropylpyridine lands on safety profiles similar to those of other alkylated pyridines—low vapor pressure means reduced risk of inhalation exposure, and reactivity remains manageable under ambient conditions. Still, careful storage in a cool, dry space protects both user health and chemical lifespan.
Over the years, I’ve learned that familiarity with handling larger parent classes—like pyridine or acetophenone—serves as sufficient foundation for first-time users. Simple steps like wearing gloves, ensuring good ventilation, and avoiding sources of ignition keep things sensible. More important, in an academic context, is proactively sharing these habits across new student cohorts and visiting scholars. That builds long-term safety culture while also keeping compliance officers and auditors satisfied.
Now more than ever, traceable sourcing has real stakes. Interruptions in chemical supply chains, regulatory hurdles, and the growing push toward greener chemistry mean choices about lab reagents go beyond lowest cost per gram. Trustworthy suppliers back every shipment with full traceability—from lot numbers that match up with online records, to seamless reordering processes as projects scale. My teams have benefited from direct relationships with specialty providers who understand the stakes of an interrupted workflow. That level of service can matter as much as product specs, or even more in the middle of a high-intensity, deadline-driven campaign.
Access to regulatory documentation, impurity profiles, and transparent QA/QC histories keeps everyone on the same page. In food, fragrance, or pharma settings, auditors expect nothing less. Any material that cuts corners in this day and age deserves a second look—or a hard pass. Advocacy for transparent sourcing and proper recordkeeping doesn’t only protect research investments, it provides a quality baseline that upholds trust between labs and customers downstream.
Growth in sustainable chemistry circles compels researchers to review every chemical’s life cycle, from manufacture to disposal. 3-Acetyl-2-isopropylpyridine, like its counterparts, faces evolving scrutiny not just for technical performance but also for environmental impact. Over the last decade, I’ve seen a welcome shift: suppliers increasingly share details about production methods, potential for byproduct recovery, and options for recycling or safe disposal. Minimizing waste and cutting back on hazardous residuals adds up, especially in high-throughput environments or in production scale-ups connected to consumer brands.
Forward-thinking labs look ahead. They select compounds that slot into closed-loop processes, participate in alternative solvent systems, or fit into circular chemistry programs. Conversations with production chemists and scale-up engineers highlight how mid-sized molecules like 3-Acetyl-2-isopropylpyridine can sometimes serve double-duty, for example, acting as both flavor intermediates and synthetic stepping stones in greener pathways. Supporting documentation on biodegradability, waste-handling protocols, and environmental exposure round out risk assessments, ensuring designers have a full-view of compound impact before green-lighting new projects.
Real-world use brings a string of pragmatic challenges. Any time a new compound arrives, teams want to know how it behaves in both standard protocols and less typical set-ups. In our lab’s routine, we always inventory initial sample batches, note the bottle fill level, check tamper seals, and log expiration or retest dates against our central software. We check compatibility with solvent systems and standard TLC or HPLC markers on Day One, making it easy to catch any behavior that diverges from expected references.
For 3-Acetyl-2-isopropylpyridine, clear appearance and smooth transfer with minimal static are practical plusses. I’ve picked up little tricks over the years: pre-warming viscous samples makes pipetting less of a headache; storing bottles near silica desiccators cuts back on water absorption in humid summers. Cross-checking reported melting and boiling points against published benchmarks (when available) lets teams spot off-batch anomalies early, reducing uncertainty that could ripple into wasted effort or botched experiment timelines.
Teams planning downstream chemical reactions should run a small-scale pilot batch with analytical backup, logging retention times and spectral characteristics across standard platforms. In a pinch, they can reach out to supplier technical support. Labs that train incoming team members on these practicalities see faster project uptake and less rework—not just for this compound, but for any new building block in the pipeline.
The landscape for fine chemicals shifts all the time, tracking alongside international regulations, batch-size requirements, and demand from evolving industries. Over the last several years, 3-Acetyl-2-isopropylpyridine has moved from niche catalog listing to a recognized pick in many procurement shortlists. This uptick follows a broader interest in fine-tuned flavor development, precision pharmaceutical synthesis, and the trend toward replacing more volatile or less selective analogs.
In my own procurement experience, price-per-gram swings depending on grade, origin, and order scale. Institutions that place repeat orders can often negotiate better terms, while smaller labs may pool purchases or join consortia to access greater discounts. Fluctuations in raw material costs, environmental levies, and shipping timelines all feed into final delivered price. Transparency in packaging—volume, net weight, and compatibility with standard secondary containers—makes downstream use and inventory tracking less of a guessing game.
A glance at recent patents and research papers shows 3-Acetyl-2-isopropylpyridine in continuous use, not tucked away as a legacy reagent. Its distinct reactivity profile, paired with a low tendency for unwanted side-reactions, opens up new synthetic possibilities in both established and emerging industries. Diverse applications mean that even as regulations tighten and research priorities pivot, the underlying value of this compound stays significant.
Emerging data points to expanding roles: catalyst precursor, ligand design, flavor mimic development, and scaffold for new medicinal chemistry efforts. Each of these roles requires unwavering confidence in the input chemical’s consistency and traceability. The pace of innovation only accelerates as teams share results—both successful and off-target—across global digital platforms. As a result, compounds with well-documented histories like 3-Acetyl-2-isopropylpyridine earn mindshare and market share alike.
While labs continue to face logistical and sourcing challenges—supply chain disruptions, evolving import/export controls, and quality variation between batches—there are effective solutions on the table. Direct partnerships with reputable specialty chemical providers allow for advanced notice of policy changes, batch delays, or raw material constraints. Investment in in-house analytical capacity allows labs to verify incoming material rather than relying solely on supplier attestation—arming researchers with rapid feedback when timelines turn critical.
Scaling up relationships with third-party auditing and validation services brings greater accountability and peace of mind for both research and production teams. Intra-industry forums and collaborative purchasing consortia provide economies of scale and knowledge sharing—democratizing access that was once limited to well-funded labs. As organizations transition to more sustainable sourcing, ongoing dialogue with manufacturers about process improvements, waste minimization, and alternatives to legacy reagents opens doors to broader impact.
Choosing any reagent for your process—especially something as distinctive as 3-Acetyl-2-isopropylpyridine—deserves careful thought. Teams taking the time to review supplier documentation, batch histories, and performance data consistently report higher satisfaction and fewer downstream surprises. Reliable compounds build better research. Products with traceable provenance, transparent safety information, and responsive customer support provide not only peace of mind, but a foundation for innovation.
Moving forward, scientists and procurement specialists who frame their sourcing strategies around robust data, peer insights, and direct experience will keep their operations ready for whatever challenges arise. Whether your application lies in flavor and fragrance development, pharmaceutical design, analytical chemistry, or process engineering, 3-Acetyl-2-isopropylpyridine demonstrates that thoughtfully selected reagents make all the difference—day in and day out.
