Difference between revisions of "Born–Haber cycle"

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The '''Born–Haber cycle''' is a particular application of [[Hess's law]] to deduce the changes in [[enthalpy]] for reactions involving gaseous ions, particularly the determination of [[Lattice energy|lattice enthalpies]].<ref name="Atkins">{{Atkins4th|pages=49–52}}.</ref> It is named after the German scientists [[Max Born]] (1882–1970) and [[Fritz Haber]] (1868–1934).
 
The '''Born–Haber cycle''' is a particular application of [[Hess's law]] to deduce the changes in [[enthalpy]] for reactions involving gaseous ions, particularly the determination of [[Lattice energy|lattice enthalpies]].<ref name="Atkins">{{Atkins4th|pages=49–52}}.</ref> It is named after the German scientists [[Max Born]] (1882–1970) and [[Fritz Haber]] (1868–1934).
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As with other applications of Hess's law, the Born–Haber cycle relies on the fact that enthalpy is a [[state function]], that is that the change in enthalpy between two states of a system is independent of the path taken to change the state. In a Born–Haber cycle, the path is cyclical, with the initial and final states being identical, so Δ''H''&nbsp;=&nbsp;0. This allows a single unknown enthalpy change along the path to be calculated by reference to the others. Born–Haber cycles can also be constructed for other state functions, such as [[internal energy]], [[entropy]] and [[Gibbs energy]].
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==Lattice enthalpy==
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{{main|Lattice energy}}
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The lattice enthalpy of an [[ionic compound]] MX is the enthalpy change for the reaction<ref group="note">The lattice enthalpy is conventionally defined as the production of gaseous ions so that it is positive for all solids.</ref>
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:MX (cr) &rarr; M<sup>+</sup> (g) + X<sup>−</sup> (g)
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It cannot be measured directly, as the ions cannot be sufficiently separated in the gas state: in practice, all ionic compounds vaporize to covalent molecules.
  
 
==Notes and references==
 
==Notes and references==

Revision as of 08:09, 12 April 2011

The Born–Haber cycle is a particular application of Hess's law to deduce the changes in enthalpy for reactions involving gaseous ions, particularly the determination of lattice enthalpies.[1] It is named after the German scientists Max Born (1882–1970) and Fritz Haber (1868–1934).

As with other applications of Hess's law, the Born–Haber cycle relies on the fact that enthalpy is a state function, that is that the change in enthalpy between two states of a system is independent of the path taken to change the state. In a Born–Haber cycle, the path is cyclical, with the initial and final states being identical, so ΔH = 0. This allows a single unknown enthalpy change along the path to be calculated by reference to the others. Born–Haber cycles can also be constructed for other state functions, such as internal energy, entropy and Gibbs energy.

Lattice enthalpy

The lattice enthalpy of an ionic compound MX is the enthalpy change for the reaction[note 1]

MX (cr) → M+ (g) + X (g)

It cannot be measured directly, as the ions cannot be sufficiently separated in the gas state: in practice, all ionic compounds vaporize to covalent molecules.

Notes and references

Notes

  1. The lattice enthalpy is conventionally defined as the production of gaseous ions so that it is positive for all solids.

References

  1. Atkins, P. W. Physical Chemistry, 4th ed.; University Press: Oxford, 1990; pp 49–52. ISBN 0-19-855283-1.

External links

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