LHYPERFINE: Difference between revisions
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Description: compute the hyperfine tensors at the atomic sites (available as of vasp.5.3.2). | Description: compute the hyperfine tensors at the atomic sites (available as of vasp.5.3.2). | ||
---- | ---- | ||
To have VASP compute the hyperfine tensors at the atomic sites, set | |||
LHYPERFINE = .TRUE. | |||
== Related | The hyperfine tensor A<sup>I</sup> describes the interaction between a nuclear spin S<sup>I</sup> (located at site '''R'''<sub>I</sub>) and the electronic spin distribution S<sup>e</sup> (in most cases associated with a paramagnetic defect state): | ||
:<math> | |||
E=\sum_{ij} S^e_i A^I_{ij} S^I_j | |||
</math> | |||
In general it is written as the sum of an isotropic part, the so-called Fermi contact term, and an anisotropic (dipolar) part. | |||
The Fermi contact term is given by | |||
:<math> | |||
(A^I_{\mathrm{iso}})_{ij}= \frac{2}{3}\frac{\mu_0\gamma_e\gamma_I}{\langle S_z\rangle}\delta_{ij}\int \delta_T(\mathbf{r})\rho_s(\mathbf{r}+\mathbf{R}_I)d\mathbf{r} | |||
</math> | |||
where ρ<sub>s</sub> is the spin density, μ<sub>0</sub> is the magnetic susceptibility of free space, | |||
γ<sub>e</sub> the electron gyromagnetic ratio, γ<sub>I</sub> the nuclear gyromagnetic ratio of the nucleus at '''R'''<sub>I</sub>, and <math>\langle S_z \rangle</math> the expectation value of the ''z''-component of the total electronic spin. | |||
δ<sub>T</sub>('''r''') is a smeared out δ function, as described in | |||
the Appendix of Ref.<ref name="bloechl:prb:00"/>. | |||
The dipolar contributions to the hyperfine tensor are given by | |||
:<math> | |||
(A^I_{\mathrm{ani}})_{ij}=\frac{\mu_0}{4\pi}\frac{\gamma_e\gamma_I}{\langle S_z\rangle} | |||
\int \frac{\rho_s(\mathbf{r}+\mathbf{R}_I)}{r^3}\frac{3r_ir_j-\delta_{ij}r^2}{r^2} d\mathbf{r} | |||
</math> | |||
In the equations above ''r''=|'''r'''|, ''r''<sub>i</sub> the i-th component of '''r''', and '''r''' is | |||
taken relative to the position of the nucleus '''R'''<sub>I</sub>. | |||
The nuclear gyromagnetic ratios should be specified by means of the {{TAG|NGYROMAG}}-tag: | |||
NGYROMAG = gamma_1 gamma_2 ... gamma_N | |||
where one should specify one number for each of the ''N'' species on the {{FILE|POSCAR}} file. | |||
If one does not set {{TAG|NGYROMAG}} in the {{FILE|INCAR}} file, VASP assumes a factor of 1 for each species. | |||
As usual, all output is written to the {{FILE|OUTCAR}} file. VASP writes three blocks of data, that look | |||
something like: | |||
<pre> | |||
Fermi contact (isotropic) hyperfine coupling parameter (MHz) | |||
------------------------------------------------------------- | |||
ion A_pw A_1PS A_1AE A_1c A_tot | |||
------------------------------------------------------------- | |||
1 ... ... ... ... ... | |||
.. ... ... ... ... ... | |||
------------------------------------------------------------- | |||
</pre> | |||
with an entry for each ion on the POSCAR file. | |||
A<sub>pw</sub>, A<sub>1PS</sub>, A<sub>1AE</sub>, and A<sub>1c</sub> are the plane wave, pseudo one-center, all-electron one-center, and one-center core contributions to the Fermi contact term, respectively. | |||
The total Fermi contact term is given by A<sub>tot</sub>. Beware: for the moment we | |||
have chosen '''NOT''' to include the core contributions A<sub>1c</sub> in A<sub>tot</sub>. | |||
If you so want, you should add them by hand to A<sub>tot</sub>. | |||
Core electronic contributions to the Fermi contact term are calculated in the frozen valence approximation as proposed by Yazyev ''et al.''<ref name="yazyev:prb:05"/> | |||
The dipolar constributions are listed next: | |||
<pre> | |||
Dipolar hyperfine coupling parameters (MHz) | |||
--------------------------------------------------------------------- | |||
ion A_xx A_yy A_zz A_xy A_xz A_yz | |||
--------------------------------------------------------------------- | |||
1 ... ... ... ... ... ... | |||
.. ... ... ... ... ... ... | |||
--------------------------------------------------------------------- | |||
</pre> | |||
Again one line per ion in the POSCAR file. | |||
The total hyperfine tensors are written as: | |||
<pre> | |||
Total hyperfine coupling parameters after diagonalization (MHz) | |||
(convention: |A_zz| > |A_xx| > |A_yy|) | |||
---------------------------------------------------------------------- | |||
ion A_xx A_yy A_zz asymmetry (A_yy - A_xx)/ A_zz | |||
---------------------------------------------------------------------- | |||
1 ... ... ... ... | |||
.. ... ... ... ... | |||
---------------------------------------------------------------------- | |||
</pre> | |||
i.e., the tensors have been diagonalized and rearranged. | |||
'''N.B.''': The Fermi contact term is strongly dominated by the all-electron one-center contribution A<sub>1AE</sub>. | |||
Unfortunately, this particular term is quite sensitive to the number and eigenenergy of the all-electron partial waves that | |||
make up the one-center basis set, ''i.e.'', to the particulars of the PAW dataset you are using. | |||
As a result the Fermi contact term may strongly depend on the choice of PAW dataset. | |||
=== Units === | |||
The Fermi contact term <math>A</math> is measured in following units | |||
<math>[A]= | |||
\left[\mu_0\right]\times | |||
\left[g_e \mu_e\right]\times | |||
\left[g_j \mu_j\right]\times | |||
\left[|\psi(0)|^2\right] = | |||
\frac{T^2m^3}{J}\times | |||
\frac{J}{T}\times | |||
\frac{MHz}{T}\times | |||
\frac{1}{m^3} = MHz | |||
</math> | |||
with <math>\mu_0=4\pi\times 10^{-7} T^2 m^3 J^{-1}</math>, <math>g_e\mu_e=9.28476377\times 10^{-24} J T^{-1}, |\psi(0)|^2=10^{30}m^{-3}</math>. | |||
{{TAGBL|NGYROMAG}} is given in units of MHz/T, see [https://en.wikipedia.org/wiki/Gyromagnetic_ratio#For_a_nucleus here] for a table of different gyromagnetic ratios. | |||
== Related tags and articles == | |||
{{TAG|NGYROMAG}} | {{TAG|NGYROMAG}} | ||
{{sc|LHYPERFINE|Examples|Examples that use this tag}} | |||
== References == | |||
<references> | |||
<ref name="bloechl:prb:00">[http://link.aps.org/doi/10.1103/PhysRevB.62.6158 P. E. Blöchl, Phys. Rev. B 62, 6158 (2000).]</ref> | |||
<ref name="yazyev:prb:05">[http://link.aps.org/doi/10.1103/PhysRevB.71.115110 O. V. Yazyev, I. Tavernelli, L. Helm, and U. R. Röthlisberger, Phys. Rev. B 71, 115110 (2006).]</ref> | |||
</references> | |||
---- | ---- | ||
[[Category:INCAR]] | [[Category:INCAR tag]][[Category:NMR]][[Category:Chemical shifts]] |
Latest revision as of 14:32, 8 April 2022
LHYPERFINE = .TRUE. | .FALSE.
Default: LHYPERFINE = .FALSE.
Description: compute the hyperfine tensors at the atomic sites (available as of vasp.5.3.2).
To have VASP compute the hyperfine tensors at the atomic sites, set
LHYPERFINE = .TRUE.
The hyperfine tensor AI describes the interaction between a nuclear spin SI (located at site RI) and the electronic spin distribution Se (in most cases associated with a paramagnetic defect state):
In general it is written as the sum of an isotropic part, the so-called Fermi contact term, and an anisotropic (dipolar) part.
The Fermi contact term is given by
where ρs is the spin density, μ0 is the magnetic susceptibility of free space, γe the electron gyromagnetic ratio, γI the nuclear gyromagnetic ratio of the nucleus at RI, and the expectation value of the z-component of the total electronic spin.
δT(r) is a smeared out δ function, as described in the Appendix of Ref.[1].
The dipolar contributions to the hyperfine tensor are given by
In the equations above r=|r|, ri the i-th component of r, and r is taken relative to the position of the nucleus RI.
The nuclear gyromagnetic ratios should be specified by means of the NGYROMAG-tag:
NGYROMAG = gamma_1 gamma_2 ... gamma_N
where one should specify one number for each of the N species on the POSCAR file. If one does not set NGYROMAG in the INCAR file, VASP assumes a factor of 1 for each species.
As usual, all output is written to the OUTCAR file. VASP writes three blocks of data, that look something like:
Fermi contact (isotropic) hyperfine coupling parameter (MHz) ------------------------------------------------------------- ion A_pw A_1PS A_1AE A_1c A_tot ------------------------------------------------------------- 1 ... ... ... ... ... .. ... ... ... ... ... -------------------------------------------------------------
with an entry for each ion on the POSCAR file. Apw, A1PS, A1AE, and A1c are the plane wave, pseudo one-center, all-electron one-center, and one-center core contributions to the Fermi contact term, respectively. The total Fermi contact term is given by Atot. Beware: for the moment we have chosen NOT to include the core contributions A1c in Atot. If you so want, you should add them by hand to Atot. Core electronic contributions to the Fermi contact term are calculated in the frozen valence approximation as proposed by Yazyev et al.[2]
The dipolar constributions are listed next:
Dipolar hyperfine coupling parameters (MHz) --------------------------------------------------------------------- ion A_xx A_yy A_zz A_xy A_xz A_yz --------------------------------------------------------------------- 1 ... ... ... ... ... ... .. ... ... ... ... ... ... ---------------------------------------------------------------------
Again one line per ion in the POSCAR file.
The total hyperfine tensors are written as:
Total hyperfine coupling parameters after diagonalization (MHz) (convention: |A_zz| > |A_xx| > |A_yy|) ---------------------------------------------------------------------- ion A_xx A_yy A_zz asymmetry (A_yy - A_xx)/ A_zz ---------------------------------------------------------------------- 1 ... ... ... ... .. ... ... ... ... ----------------------------------------------------------------------
i.e., the tensors have been diagonalized and rearranged.
N.B.: The Fermi contact term is strongly dominated by the all-electron one-center contribution A1AE. Unfortunately, this particular term is quite sensitive to the number and eigenenergy of the all-electron partial waves that make up the one-center basis set, i.e., to the particulars of the PAW dataset you are using. As a result the Fermi contact term may strongly depend on the choice of PAW dataset.
Units
The Fermi contact term is measured in following units
with , . NGYROMAG is given in units of MHz/T, see here for a table of different gyromagnetic ratios.