2-Pyrrolidin-1-ylethanol, sometimes spotted under the chemical formula C6H13NO, often grabs the attention of industry professionals and lab workers for its versatile applications. This organic compound, bearing the CAS number 616-23-9, stands out thanks to a mix of both physical and chemical properties that make it a common player in pharmaceutical and chemical manufacturing lines. As a liquid or, in some cases, a crystal-like solid, its structure features a pyrrolidine ring bound to an ethanol group, giving it both solubility in water and a particular stability under standard storage conditions. This compound finds its way into processes involving complex syntheses due to its ability to act as an intermediate, especially for those working on fine chemicals or specialty raw materials.
Several industries look toward 2-Pyrrolidin-1-ylethanol for its role as a handy raw material, especially in the assembly of pharmaceutical actives, specialty chemicals, and coatings. Its molecular structure provides a backbone that helps chemists build more complex molecules, such as certain drug candidates or custom intermediates needed for research and development. Some coating manufacturers use it thanks to its specific interaction with other reactants, and there's ongoing interest from the agrochemical world because its derivatives sometimes fit new application profiles. Labs receive shipments as a liquid in sealed liter containers, sometimes as a powder, flakes, or even solid pearls, catering to workflow needs. This flexibility supports not just safety from a supply chain perspective but also ensures it integrates well into existing processes.
At room temperature, 2-Pyrrolidin-1-ylethanol may appear as either a clear liquid or, after prolonged storage in cooler environments, as small, colorless crystals. Its specific gravity sits around 0.98, aligning it close to water, which helps with certain blending operations. This molecular structure, built from a pyrrolidine ring attached to a hydroxyethyl side chain, supports solubility both in water and many organic solvents. Such solubility often means easier cleanup and product preparation in both large-scale reactors and smaller bench-top experiments. High assay levels—often 98 percent or higher—define commercial lots, letting manufacturers confidently avoid unwanted side reactions during precision work. As far as storage goes, standard drums or glass containers, away from fumes and high temperatures, give the most stability.
Global trade for this chemical often slots it under HS Code 2933990090, keeping it distinct from other heterocyclic alcohols in shipment or regulatory documentation. The chemical formula C6H13NO frames a molecule with a molecular weight of about 115.17 g/mol, making calculating mixes and solutions straightforward. Chemists appreciate the consistency, since errors in estimating concentration or charge could spark problems further down the line.
Most shipments arrive as a clear, colorless to pale-yellow liquid, but colder storage sometimes yields crystalline flakes or solidified blocks. When ordered as a powder or pearls, the material offers measured dosing and reduced risk of spillage, which makes for safer handling in both research and manufacturing setups. Density checks run close to 0.98 g/cm³, reinforcing its compatibility with water-based solutions. Some batches may show minor coloration, especially if stored improperly, but well-sealed containers usually keep quality intact for several months under room temperature.
Dissolving 2-Pyrrolidin-1-ylethanol in water or compatible organic solvents, lab workers can shape solutions for a variety of test and process purposes. Whether aiming for dilute concentrations for analytical work or saturated solutions serving as precursors, this flexibility matters. Solution characteristics remain steady due to the molecular makeup, which can resist slight pH fluctuations and short-term exposure to air. Over time, standard practice involves labeling each solution with exact concentrations and storage codes, supporting reproducibility and traceability in regulated environments.
Any chemical with this much reactivity needs respect in handling. Safety data often tags 2-Pyrrolidin-1-ylethanol as an irritant if splashed on skin or eyes. Adequate ventilation and use of gloves, goggles, and, if possible, full lab coats help cut down risks when pouring, mixing, or sampling. Spilled material should be mopped up right away with absorbent materials, as leaving it exposed could increase the risk of harmful vapors or unwanted reactions. Disposal follows local hazardous waste codes, usually flagged for organic bases, ensuring no accidental release into waterways or air. Long-term, storing this material in tightly sealed bottles, marked clearly with its chemical name and hazard class, helps prevent mishaps in crowded storage areas.
Understanding specifics such as density, formula, appearance, and safety profile means professionals can rely on 2-Pyrrolidin-1-ylethanol for everything from batch manufacturing to routine lab work. Skipping shortcuts around safe handling or disregarding product spec sheets could catch up fast, putting workers at risk or wasting expensive materials. Industry regulations push for tight adherence to best practices, not just for legal compliance but because experienced hands have seen how quickly a simple mistake can snowball. With demand growing for high-purity intermediates, knowing every detail about the raw materials people use—right down to density and hazard code—makes the difference in keeping operations safe and productive.
