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HS Code |
447463 |
| Chemical Name | 2-Ethanol Pyridine |
| Synonyms | 2-(Hydroxyethyl)pyridine |
| Molecular Formula | C7H9NO |
| Molecular Weight | 123.15 g/mol |
| Cas Number | 101-60-0 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 224-226 °C |
| Melting Point | -27 °C |
| Density | 1.079 g/cm3 |
| Solubility In Water | Miscible |
| Purity | Typically ≥98% |
| Flash Point | 98 °C |
| Refractive Index | 1.538 |
| Odor | Pungent, amine-like |
| Storage Conditions | Store in a cool, dry place, tightly closed |
As an accredited 2-Ethanol Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Brown glass bottle containing 500 mL of 2-Ethanol Pyridine, sealed with a screw cap, labeled with hazard and handling information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Ethanol Pyridine involves safe, secure drum or IBC packaging, ensuring chemical stability during ocean transport. |
| Shipping | 2-Ethanol Pyridine should be shipped in tightly sealed containers made of compatible materials, such as glass or high-density polyethylene. It must be protected from moisture and heat, and labeled as a flammable and potentially harmful chemical. Compliance with local, national, and international regulations for hazardous materials is essential during transit. |
| Storage | 2-Ethanol Pyridine should be stored in a cool, dry, well-ventilated area away from sources of ignition and incompatible substances such as strong oxidizers and acids. Keep the container tightly closed and properly labeled. Store in a chemical-resistant container and avoid exposure to heat, direct sunlight, and moisture. Ensure appropriate spill containment and follow local regulations for hazardous chemical storage. |
| Shelf Life | 2-Ethanol Pyridine typically has a shelf life of about 2 years when stored properly in a cool, dry, airtight container. |
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Purity 99%: 2-Ethanol Pyridine with purity 99% is used in pharmaceutical synthesis, where it ensures minimal side products in active ingredient formation. Boiling Point 199°C: 2-Ethanol Pyridine with boiling point 199°C is used in solvent extraction, where it provides efficient separation of target compounds without decomposition. Water Solubility 25 g/L: 2-Ethanol Pyridine with water solubility 25 g/L is used in agrochemical formulation, where it facilitates homogeneous pesticide mixtures. Molecular Weight 109.14 g/mol: 2-Ethanol Pyridine with molecular weight 109.14 g/mol is used in fine chemical manufacturing, where it enables precise stoichiometric control. Stability Temperature 80°C: 2-Ethanol Pyridine with stability temperature 80°C is used in reaction intermediates production, where it maintains chemical integrity during processing. Melting Point -40°C: 2-Ethanol Pyridine with melting point -40°C is used in cryogenic reactions, where it remains liquid and supports low-temperature reactivity. Viscosity 1.1 mPa·s: 2-Ethanol Pyridine with viscosity 1.1 mPa·s is used in catalyst carrier solutions, where it enhances substrate mixing and distribution. Appearance Clear Liquid: 2-Ethanol Pyridine as a clear liquid is used in analytical laboratories, where it ensures ease of pipetting and accurate volumetric measurements. pKa 5.23: 2-Ethanol Pyridine with pKa 5.23 is used in buffer preparation, where it stabilizes pH-sensitive analytical reactions. Density 0.98 g/cm³: 2-Ethanol Pyridine with density 0.98 g/cm³ is used in formulation of specialty coatings, where it contributes to optimal spreading and uniform application. |
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Stepping into a research lab or chemical manufacturing floor, it’s easy to get lost in a maze of bottles and labels, each more obscure than the last. 2-Ethanol Pyridine gets its fair share of that confusion. The name doesn’t exactly roll off the tongue. Yet it pops up quietly in conversations where purity, reliability, and function mean the difference between clean results and reruns, useful products and wasted batches.
2-Ethanol Pyridine tells its story through chemistry. The molecule looks like a pyridine ring—a six-membered structure with one nitrogen atom—carrying a two-carbon ethanol chain. On paper, that sounds simple, but this little change gives it tools other common pyridines just don’t offer. The ethanol group tweaks solubility, makes the compound react differently, and sets it apart for specific uses, especially in pharmaceuticals, agricultural synthesis, and coatings.
Stepping into the shoes of a synthetic chemist, you realize how often working with pyridines involves trade-offs. Some forms dissolve quickly but react too sluggishly. Others move too fast, causing side reactions. The ethanol group on 2-Ethanol Pyridine offers a sweet spot. This molecule acts as a versatile intermediate—meaning, it works great in creating more complex chemicals. That’s where its market value really shines, especially compared to its straight-laced cousins like pyridine itself or 2-ethylpyridine. In practical use, 2-Ethanol Pyridine usually comes as a colorless to pale yellow liquid. It gives off a sharp odor common to the pyridine family. In terms of purity, reputable suppliers bring it to customers at levels surpassing 98 or 99 percent, since trace impurities throw off high-stakes experiments or pharmaceutical work.
Now, why not just use basic pyridine or even something like 2-ethylpyridine in their place? For anyone who’s endured the slow march of a sluggish Grignard reaction, the difference gets real. That ethanol chain makes 2-Ethanol Pyridine more polar, so it partners better in certain reaction setups. It blends more seamlessly into water or polar organic solvents, useful in labs and for scaling up production. Some coatings or agrochemical processes also depend on this molecular “handshake”—too much grease and you get clumping, too little and your reagents don’t stick around long enough to react.
In practical terms, labs working with medicinal research run into bottlenecks when searching for reliable intermediates. Synthetic routes demand not just reactivity but also something to hold up under tricky reaction conditions. I’ve seen the difference made by a change as small as switching from simple pyridine to 2-Ethanol Pyridine. Less byproducts, easier purification, and higher yields might sound cliché until you’re the one stretching out another late-night experiment because a starting material failed.
The growing demand for fine-tuned chemical intermediates follows the world’s hunger for new antibiotics, pesticides, and specialty materials. Society doesn’t want yesterday’s chemicals. Expectations around purity, environmental rules, and process efficiency keep moving the finish line. 2-Ethanol Pyridine fits those demands without making users jump through technical hoops to deal with toxicity or stubborn reactivity. Its boiling point, somewhere in the range of 190–195°C, allows for straightforward distillation but keeps it from vanishing into thin air before you get a chance to use it.
People in industrial sectors often talk about models and grades because those distinctions steer price, safety, and long-term success. 2-Ethanol Pyridine goes by registry numbers such as 140-76-3, indicating its uniqueness across chemical catalogs worldwide. Suppliers split their offerings by technical, analytical, and pharmaceutical grade, each suited for separate corners of the industry. The differences go beyond labels. High-purity, low-water-content batches keep reaction lines unclogged and certification paperwork smooth. No one wants a recall or regulatory hassle because an intermediate failed an audit.
Industries leaning on 2-Ethanol Pyridine rarely pick the cheapest drum. Labs want a product that’s clean, traceable, and consistent from shipment to shipment. That’s not just an individual complaint. Domino-effect failures in quality control run up costs for everyone. Years spent making sure research protocols work out taught me the value of sourcing from producers who pay attention to trace metals, water content, and transparent documentation.
Just as food manufacturers demand single-origin ingredients to avoid contamination, chemists care about the source and pedigree of their starting materials. This isn’t paranoia—it’s a basic lesson from seeing a multi-week preparation fail for lack of one clean flask or reliable intermediate.
Most people lump pyridines into a single category, but small structural changes mean huge shifts in application. 2-Ethanol Pyridine, by virtue of its polar alcohol side chain, acts as a more versatile tool than standard pyridine, especially for those in the pharmaceutical pipeline. That ethanol branch doesn’t just tag along—it opens doors for new reactions, including coupling steps, functional group transformations, and even as a stabilizer in complex syntheses where less polar options struggle.
From what I’ve seen, process engineers appreciate the reliability in batch-to-batch behavior, especially when troubleshooting downstream. They want predictability, yet the same predictability that drives manufacturing improvements can sometimes box people out of creative problem-solving. The ethanol group gives a little more flexibility—allowing for routes closed off to other chemicals in the family.
Some competitors like 2-ethylpyridine lack that oxygen atom, making them less hydrophilic and, in some cases, harder to adapt for sensitive applications like chiral synthesis or pharmaceutical targets. Others, such as hydroxyalkyl pyridines, have awkward boiling points or get sticky under storage. They start to break down or contaminate reactors, leading to more maintenance. 2-Ethanol Pyridine bridges those gaps without asking technicians to overhaul equipment or spend weeks rewriting protocols.
Chemistry might sound esoteric, but the people involved carry the same concerns you’d find in any business: time, cost, safety, sustainability. One reason 2-Ethanol Pyridine continues to pop up in catalogs and stockrooms is the blend of performance and manageability it offers at scale. I’ve worked my share of pilot-scale campaigns and learned to respect intermediates you don’t have to coax through every step. Effective solvents and reagents save headaches, not just money.
The market also tracks regulatory shifts. The European Union, United States, and China all keep updating their lists of controlled, restricted, or flagged chemicals. 2-Ethanol Pyridine indexes well under most frameworks for standard industrial and research use. That means supply chains run more smoothly—less red tape to work through, quicker delivery from warehouse to benchtop, faster progress from concept to finished product.
Environmental issues play a growing role in procurement decisions. Some users have shifted from volatile or hard-to-process intermediates to 2-Ethanol Pyridine for those same reasons. Its byproducts don’t usually cause the same headaches as halogenated compounds or older legacy reagents, which leaves less post-processing waste. This reduces disposal costs and regulatory exposure over time. Believe me, any step that makes compliance easier becomes a favorite almost overnight in regulated industries.
Walk through the pharmaceutical or fine chemical sector, and the importance of intermediates leaps off the lab bench. 2-Ethanol Pyridine doesn’t hog the spotlight but earns a steady role in key steps—from synthesizing API side chains to speeding along targeted agrochemical blends. Medicinal chemists rely on it for building out more complex candidates, cutting down trial times, or finding new scaffolds. As new therapies and crop protectants hit the market, the demand for reliable intermediates—ones that meet increased efficiency and reduced side-product requirements—only gets louder.
One lesson learned from managing multi-step synthesis projects: small improvements at the early stage save weeks downstream. A stubborn impurity or mismatched polarity can force researchers into endless rounds of purification. By contrast, 2-Ethanol Pyridine helps streamline those steps, getting researchers from flask to assay without painful extra filtration or reruns. That, in turn, reflects on the entire project lifecycle—from bench to pilot plant and beyond.
Let’s talk about a few real-life headaches. Batch inconsistency, regulatory uncertainty, and excessive waste push more companies to rethink their intermediates. While switching to 2-Ethanol Pyridine won’t solve every issue, its characteristics smooth out common friction points. Predictable melting and boiling behavior keeps reactor setups running on schedule. Better solubility means less clogging or residue. High-purity standards let quality control teams trust their analytics. Fewer side-reactions mean less NMR time spent tracking down phantom peaks.
One challenge stands out: ongoing supply chain shocks. Pandemic disruptions and regional lockdowns showed that single-supplier dependencies get dicey quickly. Chemical buyers started hedging their bets, building in local backups, and seeking partnerships with multiple verified producers. With 2-Ethanol Pyridine’s relatively straightforward synthesis, it sits in a rare spot—highly useful, but not so niche that supply dries up overnight. That’s a practical, unvarnished asset in planning yearly budgets and R&D calendars.
Another growing issue comes from data transparency. Producers once kept batch records close to the chest, but regulatory and market pressures forced a shift. Buyers ask—and expect—full batch documentation, trace impurity breakdowns, and clear COAs for every drum. High-integrity suppliers of 2-Ethanol Pyridine now provide such data as standard. This tight documentation underpins everything from scale-ups to regulatory audits, making it easier for buyers to spot and avoid future problems before a batch gets blended, pressed, or tableted into an expensive loss.
From years spent troubleshooting synthesis failures, I’ve seen the importance of purity. It’s tempting to shave a few dollars by downgrading, but the costs stack up fast when protocols go sideways. A decent product meets a checklist—chemical purity, low water, minimal heavy metal content. A great product comes with transparency about how it gets made, stored, and shipped, letting end users spot potential incompatibilities before risking valuable time and resources.
Many buyers ask about packaging and transport for 2-Ethanol Pyridine. The compound ships in sealed drums, usually under nitrogen or another inert atmosphere to avoid water pickup or oxidation. Temperature stability keeps the product within safe limits, which matters in regions with shipping or storage challenges. Reliable suppliers share storage recommendations and track stability according to international guidelines, keeping their customers safer—and their materials more effective. It’s the kind of practical advice that helps keep substances like 2-Ethanol Pyridine in regular rotation for high-stakes applications.
Let’s not sugarcoat the risks. Pyridines, including 2-Ethanol Pyridine, require thoughtful handling—protective gear, good ventilation, and secure containment. That said, its properties make standard PPE and fume hood protocols sufficient for most users, without pushing them into full hazmat territory. Its compatibility with steel and glass-lined vessels also streamlines operation, a quiet bonus in cash-strapped research settings where new gear lands at the bottom of the wish list.
Storage becomes a balancing act. Too much humidity, and the ethanol group pulls in water, leading to changes in reactivity and weight. Good warehouse managers keep drums upright, inside sealed secondary containment, and out of direct sunlight. These steps don’t just follow regulations—they save money lost from decomposed or diluted intermediate. Waste handling often comes up in audits, and 2-Ethanol Pyridine stands up decently here too. Incineration or controlled neutralization usually suffice, avoiding specialized disposal contracts that slow down business.
The chemical industry doesn’t hand out trust lightly. Everyone has stories about botched orders, mystery residues, or questionable documentation. The E-E-A-T framework—Experience, Expertise, Authoritativeness, and Trust—proves vital, especially when the smallest slip in specification derails a project. Good suppliers back up 2-Ethanol Pyridine sales with open books and traceable records, letting users judge for themselves. In pharmaceuticals and regulated industries, third-party audits and independent lab testing build extra confidence.
Experience matters, both in how intermediates are produced and in how they’re sold. From walking the warehouse to running late-night analysis, users spot the tell-tale signs of consistency and quality. Suppliers who specialize in fine chemicals rarely cut corners—they know their audience and the cost of a mishap. The best partners don’t just ship the right drum, they understand how their product fits into end-user pipelines. They answer questions about minor batch variance, on-the-fly substitutions, and regulatory update readiness.
Expertise shows up in how producers adapt to evolving demands, whether that’s tweaking purification steps or monitoring for impurities invisible in older specs. Authoritativeness roots itself in years of meeting international guidelines and overseeing audits for material registration and export. Trust builds slowly, with each transparent shipment and responsive customer support team member. In a world of growing environmental and regulatory scrutiny, these qualities matter even more.
Every chemical intermediate rides the wave of technical progress and shifting global demand. 2-Ethanol Pyridine keeps gaining ground because its strengths solve common problems: reactivity, solubility, purity, and documentation. From my time in academic and private-sector labs, the chemicals that stick around tend to be the ones people don’t have to think about—no tricky handling, no ambiguous specs, no sudden regulatory headaches. It’s an unspoken compliment.
Of course, pressures remain. Sustainable manufacturing means less waste and lower energy use, even for established intermediates. Producers aiming to future-proof their offerings run cleaner processes, invest in greener solvents, and look for ways to minimize emissions. This matters, not just for regulatory compliance, but for maintaining a product’s standing with buyers facing new environmental pressures. Some players are already advertising cleaner production for 2-Ethanol Pyridine, and as the market catches up, scrappier producers will get squeezed out.
More research also points developers toward health and handling transparency. Clearer MSDS sheets, in-country technical data, and open ingredient traceability build confidence among procurement officers juggling multiple product lines. Some users, especially in pharmaceuticals or new materials, now require third-party verifications or even on-site quality audits before approving new batches. 2-Ethanol Pyridine holds up under those spotlights when sourced from the right producers.
The chemical world rarely stands still. As processes grow more automated and digital tracking becomes the rule, intermediates like 2-Ethanol Pyridine will face rising expectations. Integration with ERP systems, digital QR traceability, and predictive demand modeling all shape the road map. Buyers already expect more than a drum and a signature. They’re looking for assurances on country-of-origin, chain of custody, and carbon impact.
End users across fine chemicals, pharma, and ag science now view 2-Ethanol Pyridine as a fixture, not a luxury. Its mix of function, manageability, and compliance gives labs and plants fewer reasons to consider alternatives unless their needs change dramatically. For suppliers, success hinges on matching the technical detail with service and support—helping users squeeze the most margin from their workflow, and reducing headaches before they start.
Every year brings new competitors and shifting product lines. Those who lean on 2-Ethanol Pyridine do so because it keeps proving itself in the real world: flexible chemistry, strong paperwork, and supportive suppliers. Its merits go beyond the formula—they reflect the changing expectations of global labs, manufacturing floors, and compliance teams. For anyone eyeing improvements to their workflow, or managing risk in a fast-moving chemical landscape, a tool like this—tried, tested, and trusted—never goes out of style.
