2.5: Brønsted-Lowry Acid-Base Concept

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2.5.1: Definitions of Brønsted-Lowry Acids and Bases
The Brønsted-Lowry acid-base concept overcomes the Arrhenius system's inability to describe reactions that take place outside of aqueous solution by moving the focus away from the solution and onto the acid and base themselves. It does this by redefining acid-base reactivity as involving the transfer of a hydrogen ion, H+ , between an acid and a base. Specifically, a Brønsted acid is a substance that loses an H+ ion by donating it to a base. This means that a Brønsted base is defined as a s
2.5.2: Cations Act as Brønsted Acids in Water
Aqueous solutions of simple salts of metal ions can also be acidic, even though a metal ion cannot donate a proton directly to water to produce hydronium ions. Instead, a metal ion can act as a Lewis acid and interact with water, a Lewis base, by coordinating to a lone pair of electrons on the oxygen atom to form a hydrated metal ion.
2.5.3: Factor Affecting Brønsted Acidity and Basicity
Because the acidity of a given substance depends on the interplay between the relatively large values of its proton affinity and the energy associated with solvation of an acid's conjugate base, it can sometimes be difficult to estimate the strength of an acid in a given solvent in the absence of detailed computations. Nevertheless a variety of simple ideas may be used to roughly estimate the relative strengths of acids. These should never be substituted for a detailed consideration of solvation
2.5.4: Oxoacids and Oxoanions
Oxyacids (also known as oxoacids) are compounds of the general formula HnEOm , where E is a nonmetal or early transition metal and the acidic hydrogens are attached directly to oxygen (not E ). Oxoanions are the conjugate base species of oxoacids and behave as bases in solution. An oxo group is a oxygen atom that is bonded to a central atom but makes no other bonds.
2.5.5: Acidity of Binary Hydrides
The compounds formed between the elements and hydrogen are called binary hydrides. All such compounds can in principle act as Brønsted acids in reactions with a suitably strong base. However, as the electronegativity decreases down a group and increases from left to right across the periodic table, the acidity of binary hydrides increases.
2.5.6: Brønsted-Lowry Superacids and the Hammett Acidity Function
Superacids are able to dissociate completely because when they do so they give an extremely stable anion in which the residual negative charge is distributed among multiple electronegative atoms.
2.5.7: Acid-Base Chemistry in Amphoteric Solvents and the Solvent Leveling Effect
The Brønsted-Lowry concept allows for an understanding of hydrogen ion transfer chemistry in amphoteric protic solvents. Amphoteric protic solvents are those which can both accept and receive hydrogen ions. From the viewpoint of the Brønsted-Lowry concept the acid-base chemistry in these solvents is governed by autoionization equilibria analogous to water autoionization.

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