LORBIT: Difference between revisions

Revision as of 16:37, 8 January 2019

LORBIT = 0 | 1 | 2 | 5 | 10 | 11 | 12
Default: LORBIT = None

Description: LORBIT, together with an appropriate RWIGS, determines whether the PROCAR or PROOUT files are written.

LORBIT	RWIGS tag	files written
0	required	DOSCAR and PROCAR
1	required	DOSCAR and lm-decomposed PROCAR
2	required	DOSCAR and lm-decomposed PROCAR + phase factors
5	required	DOSCAR and PROOUT
10	ignored	DOSCAR and PROCAR
11	ignored	DOSCAR and lm-decomposed PROCAR
12	ignored	DOSCAR and lm-decomposed PROCAR + phase factors

Remark:

For LORBIT = 11 and ISYM = 2 the partial charge densities are not correctly symmetrized and can result in different charges for symmetrically equivalent partial charge densities. This issue if fixed as of version >=6. For older versions of vasp a two-step procedure is recommended:

1. Self-consistent calculation with symmetry switched on (ISYM=2)
2. Recalculation of the partial charge density with symmetry switched off (ISYM=0)

To avoid unnecessary large WAVECAR files it recommended to set LWAVE=.FALSE. in step 2

If LORBIT is set the partial charge densities can be found in the OUTCAR

total charge     

# of ion       s       p       d       tot
------------------------------------------
    1        1.514   0.000   0.000   1.514
    2        0.123   0.345   0.000   0.468

Here the first column corresponds to the ion index $\alpha$ , the s, p, d,... columns correspond to the partial charges for $l=0,1,2,\cdots$ defined as

${\displaystyle \rho_{\alpha l}=\frac{1}{N_{\bf k}} \sum_{n{\bf k}}f_{n{\bf k}} \sum_{m=-l}^{l}|\langle Y_{lm}^{\alpha}|\phi_{n\mathbf{k}}\rangle|^2 }$

The $\langle Y_{lm}^{\alpha}|\phi_{n\mathbf{k}}\rangle$ are obtained from the projection of the (occupied) wavefunctions $|\phi_{n{\bf k}}\rangle$ onto spherical harmonics that are non zero within spheres of a radius RWIGS centered at ion $\alpha$ and the last column is the sum $\sum_{l}\rho_{\alpha l}$ .

Note that depending on the system an "f" column can be found as well.

In case of collinear calculations (ISPIN=2) the magnetization densities are written to the OUTCAR

magnetization (x)
 
# of ion       s       p       d       tot
------------------------------------------
    1        0.000   0.000   0.000   0.000
    2        0.000   0.245   0.000   0.245

Here the magnetization density (projection axis is the z-axis) is calculated from the difference in the up and down spin channel ${\displaystyle m^{\alpha l}_z = \rho_{\alpha l}^{\uparrow}-\rho_{\alpha l}^{\downarrow} }$

In case of non-collinear calculations (LNONCOLLINEAR=.TRUE.) the lines after "total charge" correspond to the charge density differences in the diagonal of the density ${\displaystyle \rho_{\alpha l} = }$

the lines after "magnetization (x)" correspond to the partial magnetization density projected onto the x direction and two additional entries "magnetization (y)", "magnetization (z)" are written for the y and z direction.

Related Tags and Sections

RWIGS, PROCAR, PROOUT, DOSCAR

Examples that use this tag

Contents

@@ Line 25: / Line 25: @@
 *1. Self-consistent calculation with symmetry switched on (ISYM=2)
 *2. Recalculation of the partial charge density with symmetry switched off (ISYM=0)
-To avoid unnecessary large {{TAG|WAVECAR}} files it recommended to set {{TAG|LWAVE}}=.FALSE. in step 2.
+To avoid unnecessary large {{TAG|WAVECAR}} files it recommended to set {{TAG|LWAVE}}=.FALSE. in step 2
+If LORBIT is set the partial charge densities can be found in the {{TAGBL|OUTCAR}}
+ total charge
+ # of ion       s       p       d       tot
+ ------------------------------------------
+        1.514   0.000   0.000   1.514
+        0.123   0.345   0.000   0.468
+Here the first column corresponds to the ion index <math>\alpha</math>, the s, p, d,... columns correspond to the partial charges for <math>l=0,1,2,\cdots</math> defined as
+<math>\rho_{\alpha l}=\frac{1}{N_{\bf k}} \sum_{n{\bf k}}f_{n{\bf k}} \sum_{m=-l}^{l}|\langle Y_{lm}^{\alpha}|\phi_{n\mathbf{k}}\rangle|^2
+</math>
+The <math>\langle Y_{lm}^{\alpha}|\phi_{n\mathbf{k}}\rangle</math> are obtained from the projection of the (occupied) wavefunctions <math>|\phi_{n{\bf k}}\rangle</math> onto spherical harmonics that are non zero within spheres of a radius {{TAG|RWIGS}} centered at ion <math>\alpha</math> and
+the last column is the sum <math>\sum_{l}\rho_{\alpha l}</math>.
+Note that depending on the system an "f" column can be found as well.
+In case of collinear calculations ({{TAGBL|ISPIN}}=2) the magnetization densities are written to the {{TAGBL|OUTCAR}}
+ magnetization (x)
+ # of ion       s       p       d       tot
+ ------------------------------------------
+        0.000   0.000   0.000   0.000
+        0.000   0.245   0.000   0.245
+Here the magnetization density (projection axis is the z-axis) is calculated from the difference in the up and down spin channel <math>m^{\alpha l}_z = \rho_{\alpha l}^{\uparrow}-\rho_{\alpha l}^{\downarrow}
+</math>
+In case of non-collinear calculations ({{TAGBL|LNONCOLLINEAR}}=.TRUE.) the lines after "total charge" correspond to the charge density differences in the diagonal of the density
+<math>
+\rho_{\alpha l} =
+</math>
+ the lines after "magnetization (x)" correspond to the partial magnetization density projected onto the x direction and two additional entries "magnetization (y)", "magnetization (z)" are written for the y and z direction.
 == Related Tags and Sections ==