Faraday constant: Difference between revisions

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(New page: In chemistry and physics, the '''Faraday constant''' ''F'' is the amount of charge (in absolute value) in one mole of electrons or one mole of singly charged ions. Its value<ref>Ob...)
 
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The constant and the unit are named after the British physicist [[Michael Faraday]].
The constant and the unit are named after the British physicist [[Michael Faraday]].
Before electrons were discovered and a value for Avogadro's number was known, Faraday discovered (1833) that in [[electrolysis]] the amount of charge ''F'' necessary to deposit one mole of single-valued ions on an electrode ([[cation]]s on the cathode, [[anion]]s on the anode) is always the same, irrespective of the kind of ions. For a long time weighing the amount of silver&mdash;which in solution is the cation Ag<sup>+</sup>&mdash;deposited during electrolysis was the accepted manner of measuring electric charge and electric current.


==Reference==
==Reference==

Revision as of 09:40, 16 December 2007

In chemistry and physics, the Faraday constant F is the amount of charge (in absolute value) in one mole of electrons or one mole of singly charged ions. Its value[1] is

where NA is Avogadro's constant and e is the charge of an electron.

The constant F must be carefully distinguished from the unit F (the faraday) which is a unit of capacitance.

The constant and the unit are named after the British physicist Michael Faraday.

Before electrons were discovered and a value for Avogadro's number was known, Faraday discovered (1833) that in electrolysis the amount of charge F necessary to deposit one mole of single-valued ions on an electrode (cations on the cathode, anions on the anode) is always the same, irrespective of the kind of ions. For a long time weighing the amount of silver—which in solution is the cation Ag+—deposited during electrolysis was the accepted manner of measuring electric charge and electric current.

Reference

  1. Obtained from NIST on December 16, 2007