Advantages The primary advantages of Fischer esterification compared to other esterification processes are based on its relative simplicity. Straightforward acidic conditions can be used if acid-sensitive functional groups are not an issue; sulfuric acid can be used; weaker acids can be used with a tradeoff of longer reaction times. Because the reagents used are "direct," there is less environmental impact in terms of waste products and harmfulness of the reagents. Alkyl halides are potential
greenhouse gases or
ozone depletors,
carcinogens, and possible ecological poisons. Acid chlorides evolve
hydrogen chloride gas upon contact with atmospheric moisture, are corrosive, react vigorously with water and other nucleophiles (sometimes dangerously); they are easily quenched by other nucleophiles besides the desired alcohol; their most common synthesis routes involve the evolution of toxic
carbon monoxide or
sulfur dioxide gases (depending on the synthesis process used). Acid anhydrides are more reactive than esters because the leaving group is a
carboxylate anion—a better leaving group than an alkoxide anion because their negative charge is more delocalised. However, such routes generally result in poor
atom economy. For example, in reacting ethanol with
acetic anhydride,
ethyl acetate forms and
acetic acid is eliminated as a leaving group, which is considerably less reactive than an acid anhydride and will be left as a byproduct (in a wasteful 1:1 ratio with the ester product) if product is collected immediately. If conditions are acidic enough, the acetic acid can be further reacted via the Fischer esterification pathway, but at a much slower pace. However, in many carefully designed syntheses, reagents can be designed such that acid anhydrides are generated in situ and carboxylic acid byproducts are reactivated, and Fischer esterification routes are not necessarily mutually exclusive with acetic anhydride routes. Examples of this include the common undergraduate organic lab experiment involving the acetylation of
salicylic acid to yield
aspirin. Fischer esterification is primarily a
thermodynamically-controlled process: because of its slowness, the most stable ester tends to be the major product. This can be a desirable trait if there are multiple reaction sites and side product esters to be avoided. In contrast, rapid reactions involving acid anhydrides or acid chlorides are often
kinetically-controlled.
Disadvantages The primary disadvantages of Fischer esterification routes are its thermodynamic reversibility and relatively slow reaction rates—often on the scale of several hours to years, depending on the reaction conditions. Workarounds to this can be inconvenient if there are other functional groups sensitive to strong acid, in which case other catalytic acids may be chosen. If the product ester has a lower boiling point than either water or the reagents, the product may be distilled rather than water; this is common as esters with no protic functional groups tend to have lower boiling points than their protic parent reagents. Purification and extraction are easier if the ester product can be distilled away from the reagents and byproducts, but reaction rate can be slowed because overall reaction temperature can be limited in this scenario. A more inconvenient scenario is if the reagents have a lower boiling point than either the ester product or water, in which case the reaction mixture must be capped and refluxed and a large excess of starting material added. In this case anhydrous salts, such as
copper(II) sulfate or
potassium pyrosulfate, can also be added to sequester the water by forming
hydrates, shifting the equilibrium towards ester products. The reaction mixture containing the product can then be
decanted or filtered to remove the drying agent prior to the final
workup. ==In wine aging==