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<p><b>New page</b></p><div>{{short description|Chemical reaction which exchanges the R groups of an alcohol and ester}}<br />
{{Use dmy dates|date=September 2022}}<br />
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'''Transesterification''' is the process of exchanging the organic [[functional group]] R″ of an [[esters|ester]] with the organic group R' of an [[alcohols|alcohol]]. These reactions are often [[catalyst|catalyzed]] by the addition of an [[acid]] or [[base (chemistry)|base]] catalyst.<ref>{{cite journal|last1=Otera|first1=Junzo.|title=Transesterification|journal=Chemical Reviews|date=June 1993|volume=93|issue=4|pages=1449–1470|doi=10.1021/cr00020a004}}</ref> Strong acids catalyze the reaction by donating a [[proton]] to the [[carbonyl]] group, thus making it a more potent [[electrophile]]. Bases catalyze the reaction by removing a proton from the alcohol, thus making it more [[nucleophile|nucleophilic]]. The reaction can also be accomplished with the help of enzymes, particularly [[lipase]]s (one example is the lipase E.C.3.1.1.3<ref>{{Cite web|title=ENZYME – 3.1.1.3 Triacylglycerol lipase|url=https://enzyme.expasy.org/EC/3.1.1.3|access-date=2021-02-17|website=enzyme.expasy.org|publisher=[[Swiss Institute of Bioinformatics|SIB Swiss Institute of Bioinformatics]]}}</ref>).<br />
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[[Image:Transesterification.png|center|thumb|500px|{{center|'''Transesterification''': alcohol + ester → different alcohol + different ester}}]]<br />
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If the alcohol produced by the reaction can be separated from the reactants by distillation this will drive the [[Chemical equilibrium|equilibrium]] toward the products. This means that esters with larger [[alkoxy group]]s can be made from methyl or ethyl esters in high purity by heating the mixture of ester, acid/base, and large alcohol.<br />
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==Mechanism==<br />
In the transesterification mechanism, the carbonyl carbon of the starting ester reacts to give a [[Tetrahedral molecular geometry|tetrahedral]] intermediate, which either reverts back to the starting material, or proceeds to the transesterified product (RCOOR<sup>2</sup>). The various species exist in equilibrium, and the product distribution depends on the relative energies of the reactant and product. Depending on reaction conditions [[ester hydrolysis]] and/or [[esterification]] will also occur, which results in some amount of free carboxylic acid being present.<br />
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:[[File:General transesterification mechanism.png|500px]]<br />
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==Applications==<br />
===Polyester production===<br />
The largest scale application of transesterification is in the synthesis of [[polyester]]s.<ref name=Ullmann>Wilhelm Riemenschneider1 and Hermann M. Bolt "Esters, Organic" Ullmann's Encyclopedia of Industrial Chemistry, 2005, Wiley-VCH, Weinheim. {{doi|10.1002/14356007.a09_565.pub2}}</ref> In this application, diesters undergo transesterification with diols to form macromolecules. For example, [[dimethyl terephthalate]] and [[ethylene glycol]] react to form [[polyethylene terephthalate]] and [[methanol]], which is evaporated to drive the reaction forward.<br />
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===Methanolysis and biodiesel production===<br />
The reverse reaction, methanolysis, is also an example of transesterification. This process has been used to recycle polyesters into individual monomers (see [[plastic recycling]]). It is also used to convert fats ([[triglyceride]]s) into [[biodiesel]]. This conversion was one of the first uses. Transesterified [[vegetable oil]] ([[biodiesel]]) was used to power heavy-duty vehicles in South Africa before [[World War II]].<br />
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It was [[patented]] in the US in the 1950s by [[Colgate-Palmolive|Colgate]], though [[biolipid]] transesterification may have been discovered much earlier. In the 1940s, researchers were looking for a method to more readily produce [[glycerol]], which was used to produce [[explosives]] for World War II. Many of the methods used today by producers have their origin in the original 1940s research.<br />
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Biolipid transesterification has also been recently shown by Japanese researchers to be possible using a [[Supercritical fluid|supercritical]] methanol methodology, whereby high temperature, high-pressure vessels are used to physically catalyze the biolipid/methanol reaction into fatty-acid methyl esters.<ref>{{Cite journal |last1=Ehimen |first1=E. A. |last2=Sun |first2=Z. F. |last3=Carrington |first3=C. G. |date=2010-03-01 |title=Variables affecting the in situ transesterification of microalgae lipids |url=https://www.sciencedirect.com/science/article/pii/S0016236109004736 |journal=Fuel |volume=89 |issue=3 |pages=677–684 |doi=10.1016/j.fuel.2009.10.011 |bibcode=2010Fuel...89..677E |issn=0016-2361|url-access=subscription }}</ref><br />
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===Fat processing===<br />
[[Fat interesterification]] is used in the [[food industry]] to rearrange the [[fatty acid]]s of [[triglyceride]]s in edible [[fat]]s and [[vegetable oil]]s. For example, a solid fat with mostly saturated fatty acids may be transesterified with a vegetable oil having high unsaturated acid contents, to produce a spreadable semisolid fat whose molecules have a mix both kinds of acids.<br />
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===Synthesis===<br />
Transesterification is used to synthesize [[enol]] derivatives, which are difficult to prepare by other means. [[Vinyl acetate]], which is cheaply available, undergoes transesterification, giving access to [[enol ether|vinyl ether]]s:<ref>{{cite journal|title=Iridium-catalyzed Synthesis of Vinyl Ethers from Alcohols and Vinyl Acetate|author=Tomotaka Hirabayashi |author2=Satoshi Sakaguchi |author3=Yasutaka Ishii |journal=Org. Synth.|year=2005|volume=82|page=55|doi=10.15227/orgsyn.082.0055|doi-access=free}}</ref><ref name=Ishii>{{cite journal|title=Discussion Addendum: Iridium-catalyzed Synthesis of Vinyl Ethers from Alcohols and Vinyl Acetate|author=Yasushi Obora |author2=Yasutaka Ishii |journal=Org. Synth.|year=2012|volume=89|page=307|doi=10.15227/orgsyn.089.0307}}</ref><br />
: ROH + {{chem|AcOCH{{=}}CH|2}} ⟶ {{chem|ROCH{{=}}CH|2}} + AcOH<br />
The reaction can be effected with high enantioselectivity when mediated with a [[lipase]].<ref>{{cite book |doi=10.1002/047084289X.rv008|chapter=Vinyl Acetate |title=Encyclopedia of Reagents for Organic Synthesis |year=2001 |last1=Manchand |first1=Percy S. |isbn=0-471-93623-5 }}</ref><br />
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==See also==<br />
*[[Acetylation]]<br />
*[[Biodiesel production]]<br />
*[[Otera's catalyst]]<br />
*[[Transalkylation]]<br />
*[[Transamidification]]<br />
*[[Cocaethylene]]<br />
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==References==<br />
{{reflist}}<br />
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{{Alcohols}}<br />
{{Authority control}}<br />
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[[Category:Lipid methods]]<br />
[[Category:Reactions of esters]]<br />
[[Category:Substitution reactions]]</div>imported>Mdewman6