The intracule density, , represents the probability for the inter-electronic vector :
(13.3) |
where is the two-electron density. A simpler quantity is the spherically averaged intracule density,
(13.4) |
where is the angular part of , measures the
probability that two electrons are separated by a scalar distance . This intracule is called a position intracule.
388
Theor. Chem. Acc.
(2003),
109,
pp. 241.
Link
If
the molecular orbitals are expanded within a basis set
(13.5) |
The quantity can be expressed as
(13.6) |
where is the two-particle density matrix and is the position integral
(13.7) |
and , , and are basis functions. For HF wave functions, the position intracule can be decomposed into a Coulomb component,
(13.8) |
and an exchange component,
(13.9) |
where etc. are density matrix elements. The evaluation of
, and within Q-Chem has been described in
detail in Ref.
684
Chem. Phys. Lett.
(1999),
313,
pp. 271.
Link
.
Some of the moments of are physically significant,
392
Chem. Phys. Lett.
(1997),
270,
pp. 193.
Link
for example
(13.10) | |||||
(13.11) | |||||
(13.12) | |||||
(13.13) |
where is the number of electrons and, is the electronic dipole moment and is the trace of the electronic quadrupole moment tensor. Q-Chem can compute both moments and derivatives of position intracules.