Hund's rules: Difference between revisions

Revision as of 03:32, 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| ≤ J ≤ L+S, that labels a 2(J+1)-dimensional energy level.

Hund's rules are:^[2]

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 group of terms with a given value of S, that with the largest value of L lies lowest.
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:

^{3}P_{0}<^{3}P_{1}<^{3}P_{2}<^{1}D_{2}<^{1}P_{2}.

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:

^{3}P_{2}<^{3}P_{1}<^{3}P_{0}<^{1}D_{2}<^{1}P_{2}.

References

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

[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)

[1]

[2]

@@ Line 1: / Line 1: @@
-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.
@@ Line 8: / Line 9: @@
 # 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:
-* 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>
-^3P_{0} < ^3P_{1} < ^3P_{2} < ^1D_{2} < ^1P_{2}
+^3P_{0} < ^3P_{1} < ^3P_{2} < ^1D_{2} < ^1P_{2}.
 </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>
-^3P_{2} < ^3P_{1} < ^3P_{0} < ^1D_{2} < ^1P_{2}
+^3P_{2} < ^3P_{1} < ^3P_{0} < ^1D_{2} < ^1P_{2}.
 </math>
 ==References==
 <references />
-*L. Pauling, ''The Nature of the Chemical Bond'', Cornell University Press, Ithaca, 3rd edition (1960)
 [[Category: CZ Live]]
 [[Category: Chemistry Workgroup]]
 [[Category: Physics Workgroup]]

Hund's rules: Difference between revisions

Revision as of 03:32, 12 January 2008

References

Navigation menu

Search