STW

Synopsis

[-]stw filename

Aim

"Stewart atoms are the unique nuclear-centered spherical functions whose sum best fits a molecular electron density in a least-squares sense (Gill, P. M. W.)".[1 Gill, P. M. W.
J. Phys. Chem. 1996, 100, 15421-15427., 2Gilbert, A. T. B.; Lee, A. M.; Gill, P. M. W.
J. Mol. Struct. (Theochem) 2000, 500, 363-374.] Least-squares refinements of experimental and theoretical structure factors in reciprocal space (as done by VALRAY and XD) and ED's in real space (as done by PAMoC) provide a set of pseudoatom populations in the form of spherical harmonics tensors, that can be easily converted into traceless cartesian moments by a linear transformation. However a volume integration is needed to evaluated unabridged cartesian moments as well as a number of other atomic properties of common interest. This can be achieved by means of keyword stw.

Description

This keyword enters the pathname to an archive file on disk which contains Stewart pseudoatom properties evaluated by PAMoC through 3D volume integration. If the file does not exist, then PAMoC provides to create it and to fill it with newly calculated properties. If the file exists, but it is empty or uncomplete, PAMoC calculates the missing properties, that will be stored on the file until it is complete. Once all properties have been calculated or if the file exists and is complete, PAMoC retrieves the data on file and prints them on the output file with a clear, structured and self-explaining lay-out of the text.

The archive file contains the following integral properties for each nuclear centre:

1.	population	p_a = ∫ ρ_a(r_a) d³r_a
2.	dipole	m_a = ∫ ρ_a(r_a) r_a d³r_a
3.	quadrupole	m_a⁽²⁾ = ∫ ρ_a(r_a) r_a² d³r_a
4.	octupole	m_a⁽³⁾ = ∫ ρ_a(r_a) r_a³ d³r_a
5.	hexadecapole	m_a⁽⁴⁾ = ∫ ρ_a(r_a) r_a⁴ d³r_a
6.	volume	V_a = ∫ δ_ρ₀[ρ_a(r_a)] d³r_a where δ_ρ₀[ρ_a(r_a)] = 1 if ρ_a(r_a) ≥ ρ₀ and 0 otherwise.
7.	laplacian energy	L_a = −¼∫ ∇²ρ_a(r_a) d³r_a
8.	<r_a²>	<r_a²> = ∫ ρ_a(r_a) r_a² d³r_a
9.	Shannon entropy	S_a = −∫ ρ_a(r_a) ln ρ_a(r_a) d³r_a
10.	electric potential	φ_a(R_a) = −∫ ρ_a(r'_a) \|r'_a\|⁻¹ d³r'_a
11.	electric field	E_a(R_a) = −∫ ∇φ_a(r'_a) d³r'_a = −∫ ρ_a(r'_a) \|r'_a\|⁻³ r'_a d³r'_a
12.	electric field gradient	EFG_a(R_a) = −∫ ρ_a(r'_a) [ \|r'_a\|⁻⁵ r'_a² − \|r'_a\|⁻³ I ] d³r'_a
13.	source function self-contribution to the ED at nuclear centre	S_a(R_a) = −(1/4π) ∫ ∇² ρ_a(r'_a) \|r'_a\|⁻¹ d³r'_a
Kinetic-energy density funtionals
13.	Thomas-Fermi
13.	Weizsacker
13.	2nd order gradient expansion formula, Kirzhnits (1975)
13.	Schrodinger
13.	Lee-Yang-Parr (LYP, 1988)
13.	Thomas-Fermi
Exchange-energy density funtionals
13.	Dirac-Slater
13.	Slater
13.	X-Alpha
13.	Becke
13.	Perdew-Wang '91
13.	Modified Perdew-Wang 1991
13.	Gill 1996
13.	Perdew-Wang '86
13.	Lacks and Gordon '93
Correlation-energy density funtionals
13.	LYP version of Colle-Salvetti formula
13.	Vosko-Wilk-Nusair
Electron localization functions
13.	ELF, Tsirelson

Related Keywords

dbgmom

References

"Extraction of Stewart Atoms from Electron Densities"
Gill, P. M. W.
J. Phys. Chem. 1996, 100, 15421-15427.
"Methods for constructing Stewart atoms"
Gilbert, A. T. B.; Lee, A. M.; Gill, P. M. W.
J. Mol. Struct. (Theochem) 2000, 500, 363-374.