1H-Indole-1-propanol, 2,3-dihydro-, 1-benzoate, hydrochloride stands out as a specialty compound with a complex name hinting at its multi-part structure. Chemically, this material integrates the indole backbone, a signature molecule in both natural and synthetic chemistry circles. Add to this a propanol side chain, a benzoate ester, and a hydrochloride salt, and the result is a hybrid molecule not just with unique physical features, but a range of interesting practical applications. Molecular formula reveals itself as C18H20ClNO2, pointing to complexity and specialized use.
This compound generally appears as a crystalline solid, white or off-white, reflecting purity when handled or analyzed. Depending on synthesis and storage conditions, users may encounter it in forms such as solid flakes, powder, crystalline chunks, or fine pearls. Its texture and size distribution matter to those handling it on an industrial scale; powder adheres to gloves, crystals crunch under pressure, and flakes scatter if poured too fast. It resists liquefying under forced conditions, keeping its form until subjected to notable heat or specific solvents. Density calculation comes in close at 1.28 g/cm3, helping anyone calculating storage, shipping mass, or when mixing solutions for larger operations.
Structurally, this compound threads the indole ring and the propanol group directly, the benzoate ester clinging to the one position, while the hydrochloride brings ionic behavior and stability in moisture-rich air. This ensures shelf-stability, lets it dissolve well in water, and keeps it manageable for lab techs or production lines facing repeated preparation cycles. Solubility in polar solvents increases as the hydrochloride salt, useful in pharmaceutical or research settings for solution preparation and accuracy in dosing. The molecule stays intact in neutral and slightly acidic settings but breaks apart if conditions become strongly basic, showing why knowledgeable handling remains critical.
The compound’s HS Code falls under 2933.99 for customs and trade documentation, tagged among other heterocyclic compounds with nitrogen hetero-atoms. Specific purity requirements usually run above 98%, with impurity profiles and water content held low for safe downstream chemical synthesis or pharmacological use. Bulk shipments require strong, airtight containers; laboratory samples use amber jars or foil-wrapped vials to block light and air. Reliable sourcing draws from chemical suppliers experienced in regulated handling. Certifications and detailed analysis sheets come with purchases, meeting traceability and safety standards.
Handling any hydrochloride salt keeps you alert to its acidic tang. This one won’t fume or corrode like strong acids, but direct skin contact leads to irritation, and inhaling dust can trigger coughing or more severe respiratory reactions. Eye contamination means flushing quickly with lots of water. Lab coats, safety goggles, and gloves stay non-negotiable. Disposal follows guidelines for both organic and chloride-containing chemicals, channeling waste into approved streams to avoid environmental risks. Global Safety Data Sheets recommend working inside ventilated fume hoods and blocking unplanned spills with absorbent materials suited for organic chemistry labs.
Chemists value this material for its role as a key raw material and building block, with the indole core linking to a host of drug candidates or developmental new materials. The benzoate ester group lends itself to further modification, while the attached hydrochloride guarantees solubility in aqueous-phase reactions. Researchers in medicinal chemistry home in on its backbone to mimic or alter biological activity. Polymer scientists sometimes blend small quantities into specialty plastics for functional surface effects. Its specific configuration lets teams reduce side-product formation, streamline purification, and develop improved yield in complex synthesis runs.
Rising interest in advanced pharmaceuticals and fine chemicals keeps demand for materials like this one climbing. Every lab technician, research team, and process engineer using or producing this compound plays a part in the overall safety record and ecological footprint. Universities and industry set training that goes beyond basics, focusing on risk reduction in handling powders and stable salts. The compound’s place in trending research sectors underscores a constant push for safer, more effective, and cleaner synthesis strategies. Technologies such as remote monitoring for raw material use and digital tracking for hazardous waste can sharpen oversight and shrink waste. Small improvements in packaging, targeted education in chemical hygiene, and genuine commitment to regulatory compliance shape the future of how specialty chemicals influence society and science.
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