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Original text

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Consider the reaction below:

Cl2 + 2Fe2+ → 2Cl + 2Fe3+

The two elements involved, iron and chlorine, each change oxidation state; iron from 2+ to 3+, chlorine from 0 to 1−. There are then effectively two half-reactions occurring. These changes can be represented in formulas by inserting appropriate electrons into each half-reaction:

Fe2+ → Fe3+ + e
Cl2 + 2e → 2Cl

In the same way given two half-reactions it is possible, with knowledge of appropriate electrode potentials, to arrive at the full (original) reaction.[1]

Revised text

[edit]

Consider the reaction below:

   Cl2 + 2Fe2+ → 2Cl- + 2Fe3+

The two elements involved, iron and chlorine, each change oxidation state; iron from 2+ to 3+, chlorine from 0 to 1−. There are then effectively two half-reactions occurring. These changes can be represented in formulas by inserting appropriate electrons into each half-reaction:

   Fe2+ → Fe3+ + e-
   Cl2 + 2e- → 2Cl-

Given two half-reactions it is possible, with knowledge of appropriate electrode potentials, to arrive at the full (original) reaction the same way. The decomposition of a reaction into half-reactions is key to understanding a variety of chemical processes. For example, in the above reaction, it can be shown that this is a redox reaction in which Fe is reduced, and Cl is oxidized. Note the transfer of electrons from Fe to Cl. Decomposition is also a way to simplify the balancing of chemical equations. A chemist can atom balance and charge balance one piece of an equation at a time.

For example:

  • Fe2+ → Fe3+ + e- becomes 2Fe2+ → 2Fe3+ + 2e-
  • is added to Cl2 + 2e- → 2Cl-
  • and finally becomes Cl2 + 2Fe2+ → 2Cl- + 2Fe3+
  1. ^ Cite error: The named reference modernchemistry was invoked but never defined (see the help page).