111-61-5

Basic information

• Product Name: ETHYL STEARATE
• Synonyms: ethylstearate,mixture1:1withethylpalmitate;Radia 7185;FEMA 3490;ETHYL N-OCTADECANOATE;ETHYL OCTADECANOATE;ETHYL STEARATE;OCTADECANOIC ACID ETHYL ESTER;STEARIC ACID ETHYL ESTER
• CAS NO: 111-61-5
• Molecular Formula: C₂₀H₄₀O₂
• Molecular Weight: 312.53
• EINECS: 203-887-4
• Product Categories: Aliphatics;Fatty Acid Derivatives & Lipids;Glycerols
• Mol File: 111-61-5.mol
• Article Data: 54

Chemical Properties

• Melting Point: 34-38 °C(lit.)
• Boiling Point: 213-215 °C15 mm Hg(lit.)
• Flash Point: >230 °F
• Appearance: White/Crystalline Mass
• Density: 1.057
• Vapor Pressure: 3.01E-05mmHg at 25°C
• Refractive Index: 1.4349
• Storage Temp.: 2-8°C
• Solubility: Chloroform (Slightly), Ethyl Acetate (Slightly)
• BRN: 1788183
• CAS DataBase Reference: ETHYL STEARATE(CAS DataBase Reference)
• NIST Chemistry Reference: ETHYL STEARATE(111-61-5)
• EPA Substance Registry System: ETHYL STEARATE(111-61-5)

Safety Data

• Hazard Codes: Xi
• Statements: 36/37/38
• Safety Statements: 26-36
• WGK Germany: 2
• RTECS: WI3600000
• TSCA: Yes
• Hazardous Substances Data: 111-61-5(Hazardous Substances Data)

Usage

Description

Ethyl stearate, also known as ethyl octadecanoate, is a long-chain fatty acid ethyl ester (FAEE) that is commonly found in vegetable oils. It is a white crystalline mass with virtually no odor. Ethyl stearate is a result of the formal condensation of the carboxy group of stearic acid with the hydroxy group of ethanol.

Uses

Used in Antimicrobial Applications:
Ethyl stearate is used as an antimicrobial agent due to its ability to exhibit antimicrobial activity. This makes it a valuable component in various industries where controlling the growth of microorganisms is essential.
Used in Food Industry:
Ethyl stearate is used as a component in the volatile oil from Rhododendron anthopogonoides, which is found in various food products such as Jamaican rum, maple syrup, grapefruit juice, guava, grapes, cognac, rum, whiskey, sparkling wine, mustard, beef, cocoa, and corn oil. Its presence in these products contributes to their unique flavors and characteristics.
Used in Cosmetics and Personal Care Industry:
Ethyl stearate is used as an ingredient in the formulation of cosmetics and personal care products due to its emollient and skin-conditioning properties. It helps to provide a smooth and soft texture to the products, enhancing their performance and user experience.
Used in Pharmaceutical Industry:
Ethyl stearate is used as an excipient in the pharmaceutical industry, where it serves as a carrier or solvent for various drugs. Its ability to dissolve and stabilize active pharmaceutical ingredients makes it a useful component in the development of medications.
Used in Lubricants and Greases:
Due to its fatty acid ester nature, ethyl stearate is used as a component in the formulation of lubricants and greases. Its ability to reduce friction and wear between moving parts makes it a valuable additive in the manufacturing of these products.
Used in Plastics and Polymers:
Ethyl stearate is used as a plasticizer and softener in the plastics and polymers industry. Its incorporation into these materials improves their flexibility, workability, and overall performance.

Preparation

By esterification of ethanol with stearic acid.

Purification Methods

The solid portion is separated from the partially solid starting material, then crystallised twice from EtOH, dried by azeotropic distillation with *benzene, and fractionally distilled through a spinning-band column at low pressure [Welsh Trans Faraday Soc 55 52 1959]. [Beilstein 2 IV 1218.]

InChI:InChI=1/C20H40O2/c1-3-5-6-7-8-9-10-11-12-13-14-15-16-17-18-19-20(21)22-4-2/h3-19H2,1-2H3

Upstream product

• 555-43-1 glycerol tristearate 
• 64-17-5 ethanol 
• 141-52-6 sodium ethanolate 
• 593-29-3 potassium stearate 
• 111-62-6 oleic acid ethyl ester 
• 7619-08-1 octadeca-9,12-dienoic acid ethyl ester 
• 92177-52-1 9,12, 15-octadecatrienoic acid ethyl ester 
• 3507-99-1 silver⁽¹⁺⁾ stearate 
• 75-03-6 ethyl iodide 
• 57-11-4 stearic acid 
• 112-76-5 Stearoyl chloride 
• 5340-56-7 ethyl 2-bromostearoate 
• 5531-65-7 benzyl stearate 
• 6512-99-8 ethyl oleate 

Downstream Products

• 24514-85-0 heptatriacontane-18,20-dione 
• 64-17-5 ethanol 
• 24317-99-5 2-benzoyloctadecanoic acid ethyl ester 
• 71843-68-0 stearic acid-[1]naphthylmethyl ester 
• 86734-22-7 1,1-diphenyl-1-octadecanol 
• 112-92-5 1-octadecanol 
• 74-85-1 ethene 
• 4130-54-5 stearic acid hydrazide 
• 57-11-4 stearic acid 
• 124-26-5 stearamide 
• 111-57-9 N-stearoylethanolamine 
• 141-78-6 ethyl acetate 
• 58446-52-9 stearoylbenzoylmethane 
• 41433-81-2 diethyl 2-hexadecylmalonate 

Related news

Production of diesel fuel from renewable feeds: Kinetics of ETHYL STEARATE (cas 111-61-5) decarboxylation08/27/2019

The kinetics of liquid phase ethyl stearate decarboxylation for production of diesel fuel hydrocarbons was studied over a Pd/C catalyst in a semi-batch reactor. The kinetic behavior was tested in a wide range of temperature. Furthermore a supplementary investigation of the reaction intermediate,...detailed

Full Length ArticleDetermination of cloud point in binary and ternary mixtures containing biodiesel and diesel constituents. Part I – Ethyl palmitate, ETHYL STEARATE (cas 111-61-5) and n-hexadecane08/25/2019

Diesel fuel is being substituted by biodiesel in many countries. But, this gradual addition of biodiesel to diesel is causing problems such as the formation of sludge in storage tanks, poor engine performance, transportation difficulties and others. There is strong concern about the use of biodi...detailed

The selective hydrogenation of ETHYL STEARATE (cas 111-61-5) to stearyl alcohol over Cu/Fe bimetallic catalysts08/23/2019

Bimetallic and monometallic catalysts including Cu and/or Fe species were prepared by a co-precipitation method and their catalytic performance was tested for the selective hydrogenation of ethyl stearate to stearyl alcohol. The bimetallic catalysts were observed to be even more active for this ...detailed

Relevant articles and documents

Lipase-catalyzed esterification of stearic acid with ethanol, and hydrolysis of ethyl stearate, near the critical point in supercritical carbon dioxide

The effect of pressure on the lipase-catalyzed reaction in supercritical carbon dioxide (SCCO2) was investigated for the esterification of stearic acid (SA) with ethanol and the hydrolysis of ethyl stearate (ES) near the critical point, ranging from 6 to 20 MPa in pressure and 35 to 60°C in temperature. The esterification rate of SA began to increase near the critical point and kept increasing steadily with an increase in pressure, reflecting the increase in SA solubility in SCCO2. The hydrolysis rate of ES showed a maximum at a pressure near the critical point. When the reaction was carried out with an initial overall ES concentration below its solubility limit in SCCO2, the maximum pressure shifted along the extended line of the gas-liquid equilibrium in the supercritical region in the pressure-temperature phase plane. This seems to be related to the singular behavior of some properties in SCCO2 along this line reported in the literature. These results show the importance of pressure, as well as temperature, as a parameter to control enzyme reactions in SCCO2.

Enzymatic production of cocoa butter equivalents high in 1-palmitoyl-2-oleoyl-3-stearin in continuous packed bed reactors

This study aimed to optimize the lipase-catalyzed transesterification of high oleic sunflower oil (A) with a mixture of ethyl palmitate and ethyl stearate (B) to produce cocoa butter equivalents with a weight ratio of 1-palmitoyl-2-oleoyl-3-stearoyl-rac-glycerol (POS) to total symmetric monounsaturated triacylglycerols (SMUT) that is similar to that of cocoa butter by response surface methodology. The reaction was performed in a continuous packed bed reactor, using 0.45 g of Lipozyme RM IM as the biocatalyst. The effects of temperature (Te), residence time (RT), substrate molar ratio (SR, B/A), and water content (WC) of the substrates on the composition of reaction products were elucidated using the models established. Optimal reaction conditions for maximizing total SMUT and POS contents while minimizing the levels of diacylglycerol formation and acyl migration were: Te, 60°C; RT, 28.5 min; SR, 8.5; WC, 300 mg/kg. The contents of total SMUT, POS, and diacylglycerol in the reaction products and the content of palmitoyl and stearoyl residues at the sn-2 position of triacylglycerols in the products were 52.0, 25.1, 9.4, and 4.8 %, respectively, under these conditions. Successful scale-up of the reaction was achieved under the optimal conditions, using 5 g of the lipase. A silver-ion high performance liquid chromatography analysis showed that the products obtained by the larger scale reaction contained 49.1 % total SMUT and 6.1 % of their positional isomers.

Catalytic transfer hydrogenation of oleic acid to octadecanol over magnetic recoverable cobalt catalysts

Efficient transformation of biomass into fuel and chemicals under mild conditions with cost-effective and environmentally friendly characters is highly desirable but still challenging. Herein, a scalable and Earth-abundant cobalt catalyst was used for selective catalytic transfer hydrogenation (CTH) of unsaturated fatty acids to fatty alcohols with sustainable isopropanol as a hydrogen donor. By tuning the surface Co composition by varying the reduction temperature, the catalytic performance could be easily boosted. At 200 °C in 4 h, the optimal catalyst Co-350 (reduced at 350 °C) gives 100% oleic acid conversion with 91.9% octadecanol selectivity. Various characterization studies reveal that the co-existence of Coδ+ and Co0 over the cobalt core might be responsible for its high performance for CTH of oleic acid. This catalyst could be magnetically separated and is highly stable for reusing ten times. Moreover, this cobalt catalyst is relatively cheap and easy to scale-up, thus achieving a low-cost transformation of biomass into high value-added chemicals.

Remarkable catalytic activity of polymeric membranes containing gel-trapped palladium nanoparticles for hydrogenation reactions

Polymeric flat-sheet membranes and hollow fibers were prepared via UV photo-initiated polymerization of acrylic acid at the surface of commercial polyether sulfones (PES) membranes. These polymeric materials permitted to immobilize efficiently palladium nanoparticles (PdNP), which exhibited a mean diameter in the range of 4?6 nm. These materials were synthesized by chemical reduction of Pd(II) precursors in the presence of the corresponding support. We successfully applied the as-prepared catalytic materials in hydrogenation reactions under continuous flow conditions. Flat sheet membranes were more active than hollow fibers due to the flow configuration and defavorable operating conditions. Actually, various functional groups (i.e. C[dbnd]C, C[tbnd]C and NO2) were reduced in flow-through configuration, under mild conditions (between 1.4 and 2.2 bar H2 at 60 °C, using 3.2 mol% of Pd loading), archiving high conversions in short reaction times (12?24 s).

NATURAL BIOSURFACTANT OF ESTER AND MANUFACTURING METHOD THEREOF

The present invention relates to an ester natural surfactant and a manufacturing method thereof. The present invention relates to an eco-friendly ester natural surfactant having excellent solubility in water and biodegradability, and a manufacturing method thereof. The present invention relates to an ester natural surfactant, and more particularly, to an ester natural surfactant and a method for preparing the same. (by machine translation)