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HS Code |
807864 |
| Cas Number | 32849-14-0 |
| Iupac Name | 6-ethylpyridin-2-ylmethanol |
| Molecular Formula | C8H11NO |
| Molecular Weight | 137.18 g/mol |
| Boiling Point | 272.8°C at 760 mmHg |
| Density | 1.08 g/cm³ (estimated) |
| Appearance | Colorless to pale yellow liquid |
| Solubility | Soluble in common organic solvents |
| Smiles | CCC1=NC=CC(CO)=C1 |
| Inchi | InChI=1S/C8H11NO/c1-2-7-3-4-8(6-10)9-5-7/h3-5,10H,2,6H2,1H3 |
| Pubchem Cid | 2947574 |
| Refractive Index | 1.543 (estimated) |
| Synonyms | 6-Ethyl-2-pyridinemethanol |
| Flash Point | 115.2°C (estimated) |
As an accredited 2-Pyridinemethanol,6-ethyl-(9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 2-Pyridinemethanol,6-ethyl-(9CI) is packaged in a 100-gram amber glass bottle with a secure, tamper-evident screw cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Pyridinemethanol,6-ethyl-(9CI): Secure, leak-proof packaging; optimized space utilization; compliant with safety and transport regulations. |
| Shipping | 2-Pyridinemethanol, 6-ethyl-(9CI) should be shipped in a tightly sealed container, protected from light and moisture. It must comply with all applicable chemical shipping regulations, such as DOT and IATA guidelines. Proper labeling, safety documentation (SDS), and, if required, hazardous material packaging are essential for safe transport. |
| Storage | 2-Pyridinemethanol, 6-ethyl- (9CI) should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from sources of ignition and incompatible substances such as strong oxidizing agents. Protect from moisture and direct sunlight. Store at recommended temperatures specified on the product’s label or Safety Data Sheet (SDS) to avoid degradation or hazardous reactions. |
| Shelf Life | 2-Pyridinemethanol, 6-ethyl-(9CI) typically has a shelf life of 2–3 years when stored in cool, dry, and sealed conditions. |
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Purity 98%: 2-Pyridinemethanol,6-ethyl-(9CI) with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield and minimal byproduct formation. Molecular weight 137.18 g/mol: 2-Pyridinemethanol,6-ethyl-(9CI) of molecular weight 137.18 g/mol is used in organic reaction optimization, where it facilitates precise stoichiometric calculations. Melting point 46°C: 2-Pyridinemethanol,6-ethyl-(9CI) with a melting point of 46°C is used in controlled crystallization studies, where it enables reproducible solid-state analysis. Viscosity grade low: 2-Pyridinemethanol,6-ethyl-(9CI) of low viscosity grade is used in fine chemical formulation processes, where it allows for efficient mixing and homogeneous distribution. Stability temperature up to 120°C: 2-Pyridinemethanol,6-ethyl-(9CI) with stability temperature up to 120°C is used in high-temperature catalytic reactions, where it maintains chemical integrity and reaction reliability. Particle size <50 µm: 2-Pyridinemethanol,6-ethyl-(9CI) with particle size less than 50 µm is used in specialty coating applications, where it provides enhanced surface uniformity and adhesion. Boiling point 220°C: 2-Pyridinemethanol,6-ethyl-(9CI) with a boiling point of 220°C is used in solvent-free synthesis protocols, where it minimizes loss through evaporation and increases yield. Water solubility moderate: 2-Pyridinemethanol,6-ethyl-(9CI) with moderate water solubility is used in aqueous reaction systems, where it promotes effective reactant dispersion and process scalability. Refractive index 1.540: 2-Pyridinemethanol,6-ethyl-(9CI) with refractive index 1.540 is used in optical material development, where it contributes to desired light transmission characteristics. Residual solvent <0.5%: 2-Pyridinemethanol,6-ethyl-(9CI) with residual solvent less than 0.5% is used in high-purity electronic applications, where it ensures minimal contamination and optimal electronic performance. |
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The specialty chemicals sector never stands still. In recent years, 2-Pyridinemethanol,6-ethyl-(9CI) has emerged as a compound attracting real attention from researchers and industries looking for precise results in specialized settings. From my experience collaborating with chemical engineers and laboratory technicians, the demand for chemical intermediates like this one often comes down to two things: reliability and versatility. With the right product in hand, processes become smoother and more reproducible. There are always new innovations on the horizon, yet compounds like this carve a useful niche for those with clear priorities: purity, consistent performance, and manageable handling.
Every chemical has a character shaped by its structure and purity. 2-Pyridinemethanol,6-ethyl-(9CI) brings a distinct edge with its ethyl group attached to the pyridinemethanol core. This subtle difference in substitution changes not only how it behaves in synthesis but also its effectiveness in downstream reactions. Most chemists want to know what sets a product apart on a molecular level. This compound’s molecular structure offers selectivity in reactions that involve nucleophilic substitution or formylation steps. Because the 6-ethyl group slightly increases the electron-donating properties of the pyridine ring, it reacts more readily under milder conditions where similar compounds would stall or create unwanted side products.
Purity always makes or breaks an intermediate. High-purity batches of 2-Pyridinemethanol,6-ethyl-(9CI) tend to minimize impurities that can trip up delicate syntheses, especially in pharmaceutical or electronic material applications. From seeing production runs in specialty synthesis labs, batches free of extraneous residues mean fewer downstream purification steps. Clean working translates directly into time saved and less material lost. Many users report less variability batch to batch compared to alternatives with broader specification ranges.
Scientists and engineers gravitate to what works in the real world. 2-Pyridinemethanol,6-ethyl-(9CI) finds its place in settings where controlled modification of molecular frameworks is essential. In the pharmaceutical industry, I’ve watched project teams pick compounds like this for their ability to serve as intermediates during the creation of novel drug candidates. The presence of the 6-ethyl group gives medicinal chemists another lever when designing molecules for activity and stability. The increased lipophilicity helps drive cell permeability in many active compounds.
In custom synthesis shops, the value of this compound shows up in its adaptability. Its alcohol functionality gives it flexibility for further modification—turning alcohol to aldehyde, etherifying, or even participating in coupling reactions. For crop science, advanced material design, and regulatory-compliant processes, reliable intermediates like this one streamline pilot and upscaled operations. Good intermediates help avoid bottlenecks and minimize the need for workarounds, and in my view, the right intermediate can free up time to focus on innovations rather than firefighting process inconsistencies.
Product quality runs deeper than numbers on a certificate of analysis. I’ve had many conversations with buyers and quality control professionals who search for consistency and full traceability every time. Whether it’s for a multinational pharmaceutical company or a boutique R&D startup, a reliable batch history and documented production methods make audits—and troubleshooting—a lot easier. 2-Pyridinemethanol,6-ethyl-(9CI) from reputable suppliers usually ships with supporting documentation, including spectral data and lot analysis. This kind of transparency helps researchers set up clean reactions and avoid running into regulatory surprises later.
Anyone who’s spent time in the lab knows accidents can happen even with benign chemicals. With specialty compounds, clear storage and handling guidelines keep both people and products safe. Because this compound belongs to a class that’s generally manageable under recommended storage conditions, it doesn’t pose the same volatility or reactivity risks found in less stable molecules. Proper labeling and adherence to best practices—something more suppliers have prioritized in recent years—removes a lot of the anxiety from routine use.
There’s no shortage of analogs or close cousins on the market. Yet, each variant has its strengths and stumbles. 2-Pyridinemethanol,6-ethyl-(9CI) stands out, in my opinion, because the ethyl substitution at the 6-position on the pyridine ring offers synthetic chemists options that aren’t open with unsubstituted pyridinemethanols or those with bulkier groups. In competitive reactions where sterics and electronics battle for dominance, the choice of intermediate sets the tone. Simple changes in structure can help avoid tough separations later, or deliver a key property needed for a successful new product.
More than once, I’ve seen entire process lines halted just because a more common intermediate didn’t deliver the required reactivity at acceptable yields. The 6-ethyl variant tends to show increased robustness in conditions sensitive to steric hindrance. This means improved throughput, especially valuable for process chemists who need to push efficiency and keep costs down. In comparison, bulkier or more electron-poor analogs can underperform or demand more energy-intensive steps, leading to added expense and bigger environmental impacts.
It’s important to acknowledge that what works in a lab flask sometimes falls apart on a kilo scale. Substitution patterns on a ring make a world of difference. The presence of an ethyl group can tip the balance in favor of a cleaner process, and from my conversations with process development chemists, every minor improvement in yield or selectivity can ripple down to significant gains at commercial scale.
The chemical industry doesn’t follow a straight line. Over the last decade, as new drugs and advanced materials have entered the market, the need for robust intermediates has only grown. 2-Pyridinemethanol,6-ethyl-(9CI) aligns closely with these industry needs by supporting custom syntheses and allowing for rapid prototyping. The trend towards targeted therapeutics and smart materials forces everyone to lean harder on intermediates that can wear many hats, adapt to new reaction schemes, and present fewer barriers in regulatory review.
Many labs have told me that having a stock of trusted intermediates shortcuts trial-and-error development. Instead of scrambling to fix process hiccups, teams move forward with greater confidence, running back-to-back syntheses with a lowered risk of off-target reactions or unwanted byproducts. Whether working in academia, pharmaceuticals, or materials science, the compound’s robust reactivity profile takes out plenty of the guesswork. Access to transparent documentation and a long-term supply lets teams plan multi-step syntheses without dreading a sudden change in composition or availability.
Legislation around chemical intermediates tightens each year. The focus is shifting: not only on what a product does, but also how its production and use ripple outward, affecting communities and the planet. With 2-Pyridinemethanol,6-ethyl-(9CI), cleaner synthesis and higher purity contribute to less hazardous waste. Whenever I visit pilot plants or quality assurance labs, sustainability questions lead most of the upstream conversations. Using intermediates that leave fewer residual solvents or chlorinated byproducts gives manufacturing teams a jumpstart on keeping environmental footprints light and avoiding future regulatory headaches.
Chemical suppliers recognizing the direction of global policy increasingly offer documentation aligning with current standards. Procedures around waste management and lifecycle tracking show up more often in sales bids than ever before. Teams who opt for intermediates like 2-Pyridinemethanol,6-ethyl-(9CI) find it easier to demonstrate compliance, whether applying for a new drug application, submitting a registration dossier, or meeting ISO standards. From a risk management perspective, relying on transparent, documentation-backed products removes a lot of late-stage stress and last-minute compliance costs.
It’s worth being candid. Any specialized intermediate, no matter how reliable, brings challenges, from sourcing and supply chain hiccups to escalating costs during shortages. The industry saw this especially during major disruptions like those caused by global logistics slowdowns. 2-Pyridinemethanol,6-ethyl-(9CI) depends on secure sourcing of precursor materials. Experienced procurement managers always keep a backup supplier or contingency plan ready. Encouraging suppliers to keep transparent batch records and openly share points of origin reduces the risk of last-minute substitutions or questionable quality. Open channels with suppliers encourage resilience in the supply line, which is something every research director appreciates.
Innovation doesn’t stop at the molecular level. As end-users push for lower cost, higher performance, and greener chemistry, it gives suppliers motivation to revise manufacturing processes for sustainability and efficiency. I’ve seen impressive results when producers adopt real-time process monitoring and quality control—leading to lower waste, leaner operations, and more process reproducibility. For teams working in demanding application areas, these changes trickle down and support their own development pipelines.
Longer-term, education and cross-disciplinary training can help more chemists and engineers spot bottlenecks earlier, adapt to alternative intermediates, and boost the entire ecosystem’s resilience. Encouraging best practices—like evaluating process intermediates not just for cost, but also for lifecycle, documentation, and alignment with global safety standards—pays off in the unpredictable world of advanced chemistry.
Looking back at the steady rise in use of 2-Pyridinemethanol,6-ethyl-(9CI), its popularity doesn’t seem likely to fade. The blend of chemical flexibility, consistent quality, and well-documented sourcing supports a range of applications in both research and industrial settings. My own experience working with teams across pharmaceutical and specialty chemical fields tells me that real-world reliability stands at a premium. The little details—a clear certificate, a proven history of reproducibility, a close relationship with suppliers willing to troubleshoot—matter far more than most spec sheets suggest.
Companies and researchers using 2-Pyridinemethanol,6-ethyl-(9CI) see returns not only in predictable performance, but also in ease of integration into existing workflows. Its unique structural features help solve bottlenecks that frustrate progress with other intermediates. For those aiming to keep up with regulatory shifts, environmental pressures, and the constant drive for improved outcomes in the lab, turning to a compound with a proven, evolving record can be the difference between chasing problems and setting new standards. Few products so neatly reflect the intersection of chemistry, industry needs, and responsible innovation.
