anion

Chemistry

(noun)

A negatively charged ion, as opposed to a cation.

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(noun)

A negatively charged ion.

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(noun)

Ions that are negatively charged because they have more electrons than protons.

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Physiology

(noun)

An negatively charged ion.

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Examples of anion in the following topics:

  • Solvent Effects

    • Solvation of nucleophilic anions markedly influences their reactivity.
    • Polar, protic solvents such as water and alcohols solvate anions by hydrogen bonding interactions, as shown in the diagram below.
    • These solvated species are more stable and less reactive than the unsolvated "naked" anions.
    • Polar, aprotic solvents such as DMSO (dimethyl sulfoxide), DMF (dimethylformamide) and acetonitrile do not solvate anions nearly as well as methanol, but provide good solvation of the accompanying cations.
    • These solvent effects are more pronounced for small basic anions than for large weakly basic anions.

  • Irreversible Substitution Reactions

    • Ether solvents like tetrahydrofuran (THF) are commonly used for enolate anion formation.
    • Because of its solubility in THF, LDA is a widely used base for enolate anion formation.
    • The last example (reaction #4) is an interesting case of intramolecular alkylation of an enolate anion.
    • Characteristics that influence direct substitution of enolate anions to C or O 2
    • examples of electrophilic substitution at both carbon and oxygen for the enolate anion

  • Naming Acids and Bases

    • Acids are named by the anion they form when dissolved in water.
    • Depending on what anion the hydrogen is attached to, acids will have different names.
    • Simple acids, known as binary acids, have only one anion and one hydrogen.
    • These anions usually have the ending "-ide."
    • This chart provides the nomenclature of some common anions and acids

  • Anionic Chain-Growth Polymerization

    • This is an example of anionic polymerization, the course of which is described by the following equations.
    • Only monomers having anion stabilizing substituents, such as phenyl, cyano or carbonyl are good substrates for this polymerization technique.
    • Species that have been used to initiate anionic polymerization include alkali metals, alkali amides, alkyl lithiums and various electron sources.
    • A practical application of anionic polymerization occurs in the use of superglue.

  • Enolate Intermediates

    • Many of the most useful alpha-substitution reactions of ketones proceeded by way of enolate anion conjugate bases.
    • Since simple ketones are weaker acids than water, their enolate anions are necessarily prepared by reaction with exceptionally strong bases in non-hydroxylic solvents.
    • Esters and nitriles are even weaker alpha-carbon acids than ketones (by over ten thousand times), nevertheless their enolate anions may be prepared and used in a similar fashion.
    • The presence of additional activating carbonyl functions increases the acidity of the alpha-hydrogens substantially, so that less stringent conditions may be used for enolate anion formation.
    • To illustrate the general nucleophilic reactivity of di-activated enolate anions, two examples of SN2 alkylation reactions are shown below.

  • Ionic Radius

    • Ionic radius (rion) is the radius of an ion, regardless of whether it is an anion or a cation.
    • In this way, the sum of ionic radii of a cation and an anion can give us the distance between the ions in a crystal lattice.
    • Similarly, when an electron is added to an atom, forming an anion, the added electron repels other electrons, resulting in an increase in the size of the atom.
    • Note that this only applies if the elements are the same type of ion, either cations or anions.
    • The neutral atoms are colored gray, cations red, and anions blue.

  • Salts that Produce Acidic Solutions

    • This is due either to the presence of a metal cation that acts as a Lewis acid (which will be discussed in a later concept), or, quite commonly, due to a hydrolyzable proton in the cation or the anion.
    • Acid salts can also contain an acidic proton in the anion.
    • Examples of anions with an acidic proton include:
    • Each of these anions contains a proton that will weakly dissociate in water.
    • Therefore, salts containing these anions—such as potassium bisulfate—will yield weakly acidic solutions in water.

  • Block Copolymerization

    • At this point, our discussion will be limited to an application of anionic polymerization.
    • In the anionic polymerization of styrene, a reactive site remains at the end of the chain until it is quenched.

  • 1,2-Group Shifts

    • In this chapter rearrangements and related reactions resulting from anion induced bonding shifts will be examined.
    • In each case the driving force for the rearrangement is the conversion of a less stable anion into a more stable one.
    • A rapid proton transfer then forms the relatively stable carboxylate anion.
    • The LiAlH4 reagent not only generates the oxy-anion, but also reduces the resulting carbonyl products to alcohols.
    • An intramolecular shift of an alkyl or aryl group then creates a much more stable alkoxide anion, which in the last example eliminates cyanide anion.

  • Naming Ionic Compounds

    • An ionic compound is named first by its cation and then by its anion.
    • An ionic compound is named first by its cation and then by its anion.
    • The anion is named by taking the elemental name, removing the ending, and adding "ide."
    • To name a compound, the cation name and the anion named are added together.
    • In both systems, the name of the anion ends in -ide.