19089-92-0

Usage

Uses

Used in Food Industry:
FEMA 3354 is used as a food additive for enhancing the flavor and aroma of various food products. Its natural occurrence in fruits and beverages makes it a suitable additive for the food industry.
Used in Flavor and Fragrance Industry:
FEMA 3354 is used as a flavoring agent for imparting a fruity, pineapple, and tropical fruit odor to different products in the flavor and fragrance industry.
Used in Pharmaceutical Industry:
FEMA 3354 is used as a pharmaceutical excipient for its solubility properties, helping in the formulation and delivery of various drugs.
Used in Cosmetics Industry:
FEMA 3354 is used as a humectant and moisturizing agent in the cosmetics industry, providing hydration and improving the texture of skincare products.
Used in Industrial Applications:
FEMA 3354 is used as a solvent and intermediate in the synthesis of various chemicals, such as resins, plastics, and explosives, due to its solubility properties and ability to form esters.

Hazard

Low toxicity by ingestion and skin contact. A skin irritant.

InChI:InChI=1/C10H18O2/c1-3-5-6-7-9-12-10(11)8-4-2/h4,8H,3,5-7,9H2,1-2H3/b8-4-

Upstream product

• 623-43-8 methyl crotonate 
• 111-27-3 hexan-1-ol 

Relevant academic research and scientific papers

SO3H and NH2+ functional carbon-based solid acid catalyzed transesterification and biodiesel production

A SO3H and NH2+ functional carbon-based solid acid was used as a highly active heterogeneous catalyst for the transesterification of various carboxylic methyl esters with alcohols under mild conditions. It also showed high catalytic performance for transesterification of triolein with methanol or isopropanol. Furthermore, it was able to catalyze simultaneous esterification and transesterification of rice oil and butter respectively, the yields of biodiesel obtained were up to 94%, and the catalyst could be easily recovered and reused more than ten times without loss of activity, which indicated the carbon-based solid acid was a potential catalyst for the biodiesel industry.

New selectivities from old catalysts. Occlusion of Grubbs' catalysts in PDMS to change their reactions

This article describes new selectivities for Grubbs' first and second generation catalysts when occluded in a hydrophobic matrix of polydimethylsiloxane (PDMS). Occlusion of catalysts in mm-sized slabs of PDMS is accomplished by swelling with methylene chloride then removing the solvent under vacuum. The catalysts are homogenously dissolved in PDMS yet remain catalytically active. Many substrates that react by olefin metathesis with Grubbs' catalysts freely dissolved in methylene chloride also react by olefin isomerization with occluded catalysts. Eleven examples of substrates that exhibit dual reactivity by undergoing olefin isomerization with occluded catalysts and olefin metathesis with catalysts dissolved in methylene chloride are reported. Most of these substrates have olefins with allylic phosphine oxides, carbonyls, or ethers. Control experiments demonstrate that isomerization is occurring in the solvent by decomposition of the catalyst from a ruthenium carbene to a proposed ruthenium hydride. This work was extended by heating occluded Grubbs' first generation catalyst to 100 °C in 90% MeOH in H2O in the presence of various alkenes to transform the Grubbs' catalyst into an isomerization catalyst for unfunctionalized olefins. This work demonstrates that occlusion of organometallic catalysts in PDMS has important implications for their reactions and can be used as a method to control which reactions they catalyze.