6378-65-0

Basic information

• Product Name: Hexyl hexanoate
• Synonyms: HEXYL HEXANOATE;HEXYL HEXOATE;HEXYL CAPROATE;FEMA 2572;N-HEXANOIC ACID N-HEXYL ESTER;N-HEXYL CAPROATE;N-HEXYL HEXANOATE;N-HEXYL N-CAPROATE
• CAS NO: 6378-65-0
• Molecular Formula: C₁₂H₂₄O₂
• Molecular Weight: 200.32
• EINECS: 228-952-4
• Product Categories: G-HFlavors and Fragrances;Prepackaged Samples;Alphabetical Listings;Flavors and Fragrances
• Mol File: 6378-65-0.mol
• Article Data: 115

Chemical Properties

• Melting Point: −55 °C(lit.)
• Boiling Point: 245-246 °C(lit.)
• Flash Point: 211 °F
• Appearance: Colorless to slightly yellow liquid
• Density: 0.863 g/mL at 25 °C(lit.)
• Vapor Pressure: 0.0278mmHg at 25°C
• Refractive Index: n20/D 1.424(lit.)
• Water Solubility: 951μg/L at 20℃
• CAS DataBase Reference: Hexyl hexanoate(CAS DataBase Reference)
• NIST Chemistry Reference: Hexyl hexanoate(6378-65-0)
• EPA Substance Registry System: Hexyl hexanoate(6378-65-0)

Safety Data

• Statements: 36/37/38
• Safety Statements: 26-36/37/39-24/25
• WGK Germany: 2
• RTECS: MO8385000
• Hazardous Substances Data: 6378-65-0(Hazardous Substances Data)

Usage

Description

Hexyl hexanoate is an organic compound with a herbaceous odor, characterized by its sweet, fruity, and green aroma with tropical notes. It can be synthesized through various methods, such as passing n-hexyl alcohol over a CuO + UO3 catalyst at 220 310°C or treating n-hexyl alcohol with Ca(Br03)2 and diluted aqueous HBr at 30°C. It is known to occur naturally in a variety of fruits, vegetables, and beverages, contributing to their distinct flavors and scents.

Uses

Used in Flavor and Fragrance Industry:
Hexyl hexanoate is used as a flavoring agent for its sweet, fruity, and green aroma with tropical notes. It is particularly suitable for enhancing the taste and scent of various food products, such as fruits, jams, and beverages.
Used in Perfumery:
Hexyl hexanoate is used as a fragrance ingredient in the perfumery industry, where its herbaceous and tropical scent adds depth and complexity to perfume compositions.
Used in the Cosmetic Industry:
Hexyl hexanoate is used as a component in cosmetic formulations, such as lotions, creams, and shampoos, for its pleasant aroma and ability to provide a fresh, clean scent.
Used in the Food Industry:
Hexyl hexanoate is used as an additive in the food industry to impart a sweet, fruity, and green flavor to various products, such as fruit-flavored beverages, candies, and desserts.
Used in the Beverage Industry:
Hexyl hexanoate is used in the beverage industry to add a tropical, fruity, and green note to drinks, such as fruit juices, soft drinks, and alcoholic beverages like wine and cider.
Used in the Pharmaceutical Industry:
Hexyl hexanoate may be used in the pharmaceutical industry as a component in the development of drugs that target specific receptors or pathways, potentially leading to novel therapeutic applications.

Preparation

By passing n-hexyl alcohol over CuO + UO3 catalyst at 220 to 310°C, or by treating n-hexyl alcohol with Ca(BrO3)2 and diluted aqueous HBr at 30°C

Flammability and Explosibility

Notclassified

InChI:InChI=1/C12H24O2/c1-3-5-7-9-11-14-12(13)10-8-6-4-2/h3-11H2,1-2H3

Upstream product

• 142-62-1 hexanoic acid 
• 111-27-3 hexan-1-ol 
• 112-58-3 dihexyl ether 
• 115464-59-0 methyltrifluoromethyldioxirane 
• 66-25-1 hexanal 
• 67-56-1 methanol 
• 96-41-3 Cyclopentanol 
• 502-41-0 cycloheptanol 
• 98-85-1 1-Phenylethanol 
• 124-38-9 carbon dioxide 
• 14246-15-2 trimethylsilyl hexanoate 
• 2051-49-2 n-hexanoic anhydride 
• 100-46-9 benzylamine 
• 140-75-0 para-fluorobenzylamine 

Downstream Products

• 15719-64-9 methylammonium carbonate 
• 142-62-1 hexanoic acid 
• 5416-46-6 pentan-3-yl hexanoate 
• 5413-59-2 cyclopentyl hexanoate 
• 3460-45-5 1-phenylethyl hexanoate 
• 98-86-2 acetophenone 
• 2311-46-8 hexanoic acid isopropyl ester 
• 111-27-3 hexan-1-ol 
• 6243-10-3 cyclohexyl hexanoate 
• 6283-98-3 N-benzylhexanamide 
• 38407-00-0 N-hexylidene-1-phenylmethanamine 
• 6938-45-0 benzyl hexanoate 
• 572-09-8 2,3,4,6-tetra-O-acetyl-α-D-glucopyranosyl bromide 
• 112-58-3 dihexyl ether 

Relevant articles and documents

The key role of the latent N-H group in Milstein's catalyst for ester hydrogenation

We previously demonstrated that Milstein's seminal diethylamino-substituted PNN-pincer-ruthenium catalyst for ester hydrogenation is activated by dehydroalkylation of the pincer ligand, releasing ethane and eventually forming an NHEt-substituted derivative that we proposed is the active catalyst. In this paper, we present a computational and experimental mechanistic study supporting this hypothesis. Our DFT analysis shows that the minimum-energy pathways for hydrogen activation, ester hydrogenolysis, and aldehyde hydrogenation rely on the key involvement of the nascent N-H group. We have isolated and crystallographically characterized two catalytic intermediates, a ruthenium dihydride and a ruthenium hydridoalkoxide, the latter of which is the catalyst resting state. A detailed kinetic study shows that catalytic ester hydrogenation is first-order in ruthenium and hydrogen, shows saturation behavior in ester, and is inhibited by the product alcohol. A global fit of the kinetic data to a simplified model incorporating the hydridoalkoxide and dihydride intermediates and three kinetically relevant transition states showed excellent agreement with the results from DFT.

Solvent-free oxidation of straight-chain aliphatic primary alcohols by polymer-grafted vanadium complexes

Oxidovanadium(IV) complexes [VO(tertacac)2] (1), [VO(dipd)2] (2), and [VO(phbd)2] (3) were synthesized by reacting [VO(acac)2] with 2,2,6,6-tetramethyl-3,5-hepatanedione, 1,3-diphenyl-1,3-propanedione, and 1-phenyl-1,3-butanedione, respectively. Imidazole-modified Merrifield resin was used for the heterogenization of complexes 1–3. During the process of heterogenization, the V4+ center in complex 2 converts into V5+, whereas the other two complexes 1 and 3 remain in the oxidovanadium(IV) state in the polymer matrix. Theoretically, calculated IPA values of 1–3 suggest that 2 is prone to oxidation compared with 1 and 3, which was also supported by the absence of EPR lines in 5. Polymer-supported complexes Ps-Im-[VIVO(tertacac)2] (4), Ps-Im-[VVO2(dipd)2] (5), and Ps-Im-[VIVO(phbd)2] (6) were applied for the solvent-free heterogenous oxidation of a series of straight-chain aliphatic alcohols in the presence of H2O2 at 60°C and showed excellent substrate conversion specially for the alcohols with fewer carbon atoms. Higher reaction temperature improves the substrate conversion significantly for the alcohols containing more carbon atoms such as 1-pentanol, 1-hexanol, and 1-heptanol while using optimized reaction conditions. However, alcohols with fewer carbon atoms seem less affected by reaction temperatures higher than the optimized temperature. A decreasing trend in the selectivity(%) of carboxylic acid was observed with increasing carbon atoms among the examined alcohols, whereas the selectivity towards aldehydes increased. The order of efficiency of the supported catalysts is 4 > 6 > 5 in terms of turnover frequency (TOF) values and substrate conversion, further supported by theoretical calculations.

MOFs based on 1D structural sub-domains with Br?nsted acid and redox active sites as effective bi-functional catalysts

A novel family of lamellar MOF-type materials, which contain Br?nsted acid sites together with redox active centers, based on assembled 1D organic-inorganic nanoribbons were obtained through direct solvothermal synthesis routes, using specific monotopic benzylcarboxylate spacers with thiol substituents in thepara-position like structural modulator compounds and effective post-synthesis oxidized treatments to generate accessible sulfonic groups. Low-dimensional aluminum metal-organic materials, containing free sulfonic pendant groups (Al-ITQ-SO3H), were successfully tested in several acid reactions, such as acetalization, esterification and ring opening of epoxides with a significant impact on fine chemistry processes. The direct introduction of stabilized Pd nanoparticles, cohabitating with pendant sulfonic groups, allowed the preparation of active bi-functional MOF-type hybrid materials (Al-ITQ-SO3H/Pd) capable of carrying out one-pot two-step oxidation-acetalization reactions, exhibiting high yield and high activity during consecutive catalytic cycles.