The big picture gets bigger.
Ideas in science never stay static. One discovery builds on another. Our concepts of acids and bases have grown from the fundamental ideas of Arrhenius to Brønsted-Lowry to Lewis. Each step adds to our understanding of the world around us and makes the “big picture” even bigger.
Lewis Acids and Bases
Gilbert Lewis (1875-1946) proposed a third theory of acids and bases that is even more general than either the Arrhenius or Brønsted-Lowry theories. A Lewis acid is a substance that accepts a pair of electrons to form a covalent bond. A Lewis base is a substance that donates a pair of electrons to form a covalent bond. So, a Lewis acid-base reaction is represented by the transfer of a pair of electrons from a base to an acid. A hydrogen ion, which lacks any electrons, accepts a pair of electrons. It is an acid under both the Brønsted-Lowry and Lewis definitions. Ammonia consists of a nitrogen atom as the central atom with a lone pair of electrons. The reaction between ammonia and the hydrogen ion can be depicted as shown in Figure below.
The lone pair on the nitrogen atom is transferred to the hydrogen ion, making the NH3 a Lewis base while the H+ is a Lewis acid.
Some reactions that do not qualify as acid-base reactions under the other definitions do so under only the Lewis definition. An example is the reaction of ammonia with boron trifluoride.
Boron trifluoride is the Lewis acid, while ammonia is again the Lewis base. As there is no hydrogen ion involved in this reaction, it qualifies as an acid-base reaction only under the Lewis definition. Table below summarizes the three acid-base theories.
|Arrhenius||H+ ions in solution||OH− ions in solution|
|Brønsted-Lowry||H+ donor||H+ acceptor|
|Lewis||electron-pair acceptor||electron-pair donor|
- Lewis acids and bases are defined.
- Examples of Lewis acids and bases are given.
- What is the difference between a Lewis acid or base and a Brønsted Lowry acid or base?
- What is required to happen in Lewis acid-base reactions?
- Do all Lewis acid-base reactions involve protons?