2-Propylheptan-1-ol (CAS 10042-59-8) is a molecule whose significance in industrial chemistry belies its relatively simple structure. As a C10 branched-chain primary alcohol, its specific molecular architecture imparts unique physicochemical properties that make it a highly valued chemical intermediate. This technical overview delves into its chemical characteristics, reactivity, and the diverse applications that drive its demand in sectors such as plasticizers, polymers, and cosmetics.

Molecular Structure and Physicochemical Properties

The IUPAC name, 2-Propylheptan-1-ol, clearly defines its structure: a seven-carbon chain (heptane) with a hydroxyl group (-OH) at the first carbon and a propyl group (-CH2CH2CH3) attached to the second carbon. This branching is crucial. It differentiates it from linear alcohols like 1-decanol, influencing its boiling point (approx. 217.5°C), melting point (approx. -1.53°C), and solubility profile. It is poorly soluble in water but readily dissolves in many organic solvents, a characteristic that facilitates its use in various reaction media and product formulations. The molecule's formula is C10H22O, and its molar mass is approximately 158.28 g/mol.

Chemical Reactivity: The Foundation of Its Utility

The primary alcohol functional group (-CH2OH) is the hub of 2-Propylheptan-1-ol's reactivity. This group readily undergoes several key organic reactions:

  • Esterification: This is arguably its most industrially significant reaction. When reacted with dicarboxylic acids (like phthalic anhydride) or their derivatives, it forms esters. The ester formed with phthalic anhydride is Di(2-propylheptyl) phthalate (DPHP), a widely used plasticizer known for its excellent performance and low migration. The reaction typically requires an acid catalyst and elevated temperatures.
  • Oxidation: As a primary alcohol, it can be oxidized. Mild oxidation yields the corresponding aldehyde, 2-propylheptanal. Stronger oxidation leads to the carboxylic acid, 2-propylheptanoic acid, which itself can be a valuable intermediate.
  • Etherification: Reaction with alkyl halides or epoxides can form ethers, though this is less common industrially compared to esterification.

These reaction pathways allow 2-Propylheptan-1-ol to be transformed into a multitude of downstream products, each tailored for specific industrial needs. For any formulator or R&D chemist, understanding this reactivity is paramount when considering it as a raw material.

Industrial Applications Driving Demand

The utility of 2-Propylheptan-1-ol stems directly from its reactivity and the properties it imparts to its derivatives:

  • Plasticizers: The production of DPHP for PVC applications is a major consumer. DPHP provides flexibility, durability, and stability to PVC products used in construction, automotive, and consumer goods.
  • Cosmetics: It acts as a solvent, emollient, and fragrance component in various personal care products, contributing to texture, spreadability, and sensory experience.
  • Polymers: Derivatives like 2-propylheptyl acrylate can be used as monomers to synthesize specialty polymers and resins with enhanced hydrophobicity and weatherability for coatings and adhesives.
  • Surfactants and Lubricants: It serves as a precursor for certain specialty surfactants and high-performance lubricants.

Procurement and Supply Chain Considerations

For businesses aiming to buy 2-Propylheptan-1-ol, selecting a reliable manufacturer and supplier is crucial. NINGBO INNO PHARMCHEM CO.,LTD. is a leading chemical intermediate supplier in China, offering high-purity 2-Propylheptan-1-ol (≥98%) with consistent quality. We understand the technical demands of our clients and provide detailed product specifications, safety data sheets (SDS), and technical support. Whether you are exploring new formulations or ensuring continuity of supply, we can provide a competitive price and a dependable supply chain. We encourage you to contact us for a quote and learn more about how our high-quality products can benefit your applications.