Hund's rules: Difference between revisions

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In [[atomic spectroscopy]], '''Hund's rules''' predict which atomic energy level with quantum numbers ''L'', ''S'' and ''J'' is lowest. The rules are called after [[Friedrich Hund]] who formulated them in  1925.<ref>F. Hund, ''Zur Deutung verwickelter Spektren, insbesondere der Elemente Scandium bis Nickel.'' [On the interpretation of complicated spectra, in particular the elements scandium through nickel]. Zeitschrift für Physik, vol. '''33''', pp. 345-371 (1925).</ref> A group of atomic energy levels, obtained by [[Russell-Saunders coupling]],  is concisely indicated by a [[term symbol]]. A ''term'' (also known as ''multiplet'') is a set of simultaneous eigenfunctions of '''L'''<sup>2</sup> (total orbital angular momentum squared) and '''S'''<sup>2</sup> (total spin angular momentum squared) with given quantum numbers ''L'' and ''S'', respectively.
In [[atomic spectroscopy]], '''Hund's rules''' predict the order of atomic energy levels with quantum numbers ''L'', ''S'' and ''J''. The rules are called after [[Friedrich Hund]] who formulated them in  1925.<ref>F. Hund, ''Zur Deutung verwickelter Spektren, insbesondere der Elemente Scandium bis Nickel.'' [On the interpretation of complicated spectra, in particular the elements scandium through nickel]. Zeitschrift für Physik, vol. '''33''', pp. 345-371 (1925).</ref>  
If there is no spin-orbit coupling, the functions of one term are degenerate (have the same energy).


Hund's rules are:
A group of atomic energy levels, obtained by [[Russell-Saunders coupling]],  is concisely indicated by a [[term symbol]]. A ''term'' (also known as ''multiplet'') is a set of simultaneous eigenfunctions of '''L'''<sup>2</sup> (total orbital angular momentum squared) and '''S'''<sup>2</sup> (total spin angular momentum squared) with quantum numbers ''L'' and ''S'', respectively. If there is no spin-orbit coupling, the functions of one term are degenerate (have the same energy). If there is (weak) spin-orbit coupling it is useful to diagonalize the matrix of the corresponding operator within the ''LS'' basis in the spirit of first-order [[perturbation theory]]. This introduces the new quantum number ''J'', with |''L''-''S''| &le; ''J'' &le; ''L''+''S'', that labels a 2(''J''+1)-dimensional energy level.
Hund's rules are:<ref>L. Pauling, ''The Nature of the Chemical Bond'', Cornell University Press, Ithaca, 3rd edition (1960)</ref>


# Of the Russell-Saunders states arising from a given [[electronic configuration]] those with the largest spin quantum number ''S'' lie lowest, those with the next largest next, and so on; in other words, the states with largest spin multiplicity are the most stable.
# Of the Russell-Saunders states arising from a given [[electronic configuration]] those with the largest spin quantum number ''S'' lie lowest, those with the next largest next, and so on; in other words, the states with largest spin multiplicity are the most stable.
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# Of the states with given values of ''S'' and ''L'' in an electronic configuration consisting of less than half the electrons in a closed subshell, the state with the smallest value of ''J'' is usually the most stable, and for a configuration consisting of more than half the electrons in a closed subshell the state with largest ''J'' is the most stable.
# Of the states with given values of ''S'' and ''L'' in an electronic configuration consisting of less than half the electrons in a closed subshell, the state with the smallest value of ''J'' is usually the most stable, and for a configuration consisting of more than half the electrons in a closed subshell the state with largest ''J'' is the most stable.


The levels of the second sort, largest ''J'' most stable, can be seen as arising from holes in the closed subshell.
The levels of the second sort, largest ''J'' most stable, can be seen as arising from holes in a closed subshell.


Examples:
Examples:


* The ground state carbon atom, (1''s'')<sup>2</sup>(2''s'')<sup>2</sup>(2''p'')<sup>2</sup>, gives by [[Russell-Saunders coupling]] a set of energy levels labeled by [[term symbol]]s. Hund's rules predict the following order of the energies
* The ground state carbon atom, (1''s'')<sup>2</sup>(2''s'')<sup>2</sup>(2''p'')<sup>2</sup>, gives by [[Russell-Saunders coupling]] a set of energy levels labeled by [[term symbol]]s. Hund's rules predict the following order of the energies:
::<math>
::<math>
^3P_{0} < ^3P_{1} < ^3P_{2} < ^1D_{2} < ^1P_{2}
^3P_{0} < ^3P_{1} < ^3P_{2} < ^1D_{2} < ^1P_{2}.
</math>
</math>
* The ground state oxygen atom, (1''s'')<sup>2</sup>(2''s'')<sup>2</sup>(2''p'')<sup>4</sup>, (a two-hole state) gives by Russell-Saunders coupling a set of energy levels labeled by term symbols. Hund's rules predict the following order of the energies
* The ground state oxygen atom, (1''s'')<sup>2</sup>(2''s'')<sup>2</sup>(2''p'')<sup>4</sup>, (a two-hole state) gives by Russell-Saunders coupling a set of energy levels labeled by term symbols. Hund's rules predict the following order of the energies:
::<math>
::<math>
^3P_{2} < ^3P_{1} < ^3P_{0} < ^1D_{2} < ^1P_{2}
^3P_{2} < ^3P_{1} < ^3P_{0} < ^1D_{2} < ^1P_{2}.
</math>
</math>
==References==
==References==
<references />
<references />


*L. Pauling, ''The Nature of the Chemical Bond'', Cornell University Press, Ithaca, 3rd edition (1960)
 


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Revision as of 02:32, 12 January 2008

In atomic spectroscopy, Hund's rules predict the order of atomic energy levels with quantum numbers L, S and J. The rules are called after Friedrich Hund who formulated them in 1925.[1]

A group of atomic energy levels, obtained by Russell-Saunders coupling, is concisely indicated by a term symbol. A term (also known as multiplet) is a set of simultaneous eigenfunctions of L2 (total orbital angular momentum squared) and S2 (total spin angular momentum squared) with quantum numbers L and S, respectively. If there is no spin-orbit coupling, the functions of one term are degenerate (have the same energy). If there is (weak) spin-orbit coupling it is useful to diagonalize the matrix of the corresponding operator within the LS basis in the spirit of first-order perturbation theory. This introduces the new quantum number J, with |L-S| ≤ JL+S, that labels a 2(J+1)-dimensional energy level.

Hund's rules are:[2]

  1. Of the Russell-Saunders states arising from a given electronic configuration those with the largest spin quantum number S lie lowest, those with the next largest next, and so on; in other words, the states with largest spin multiplicity are the most stable.
  2. Of the group of terms with a given value of S, that with the largest value of L lies lowest.
  3. Of the states with given values of S and L in an electronic configuration consisting of less than half the electrons in a closed subshell, the state with the smallest value of J is usually the most stable, and for a configuration consisting of more than half the electrons in a closed subshell the state with largest J is the most stable.

The levels of the second sort, largest J most stable, can be seen as arising from holes in a closed subshell.

Examples:

  • The ground state carbon atom, (1s)2(2s)2(2p)2, gives by Russell-Saunders coupling a set of energy levels labeled by term symbols. Hund's rules predict the following order of the energies:
  • The ground state oxygen atom, (1s)2(2s)2(2p)4, (a two-hole state) gives by Russell-Saunders coupling a set of energy levels labeled by term symbols. Hund's rules predict the following order of the energies:

References

  1. F. Hund, Zur Deutung verwickelter Spektren, insbesondere der Elemente Scandium bis Nickel. [On the interpretation of complicated spectra, in particular the elements scandium through nickel]. Zeitschrift für Physik, vol. 33, pp. 345-371 (1925).
  2. L. Pauling, The Nature of the Chemical Bond, Cornell University Press, Ithaca, 3rd edition (1960)