BEXT: Difference between revisions

BEXT = [real array] 

Description: BEXT specifies an external magnetic field.

By means of the BEXT one may specify an external magnetic field that acts on the electrons in a Zeeman-like manner. This interaction is carried by an additional potential of the following form:

• For ISPIN = 2:

${\displaystyle V^{\uparrow} = V^{\uparrow} + B_{\rm ext} }$

${\displaystyle V^{\downarrow} = V^{\downarrow} - B_{\rm ext} }$

and ${\displaystyle B_{\rm ext}}$ = BEXT (in eV).

• For LNONCOLLINEAR = .TRUE.:

${\displaystyle V_{\alpha\beta} = V_{\alpha\beta} + \vec{B}_{\rm ext} \cdot \vec{\sigma}_{\alpha \beta} }$

where ${\displaystyle ({B}^x_{\rm ext}, {B}^y_{\rm ext}, {B}^z_{\rm ext})}$ = BEXT (in eV), and ${\displaystyle \vec{\sigma}}$ is the vector of Pauli matrices.

Heuristically, the effect of the above is most easily understood for the collinear spinpolarized case (ISPIN=2):

• The eigenenergies of spin-up states are raised by ${\displaystyle B_{\rm ext}}$ eV, whereas the eigenenergies of spin-down states are lowered by the same amount.

• The total energy changes by:

${\displaystyle \Delta E = (n^{\uparrow} - n^{\downarrow}) B_{\rm ext} }$ eV

where ${\displaystyle n^{\uparrow}}$ and ${\displaystyle n^{\downarrow}}$ are the number of up- and down-spin electrons in the system.

• Shifting the eigenenergies of the spin-up and spin-down states w.r.t. each other may lead to a redistribution of the electrons over these states (changes in the occupancies) and hence to changes in the density with all subsequent consequences.

The energy difference between two Zeeman-splitted electronic states is given by:

${\displaystyle \hbar \omega = g_e \mu_B B_0 }$

where ${\displaystyle \mu_B}$ is the Bohr magneton and ${\displaystyle g_e}$ is the electron g-factor.

For ISPIN=2, for purely Zeeman splitted states, we have:

${\displaystyle V^{\uparrow} - V^{\downarrow} = 2 B_{\rm ext} }$

This leads to the following relationship between our definition of ${\displaystyle B_{\rm ext}}$ (in eV) and the magnetic field ${\displaystyle B_0}$ (in T):

${\displaystyle B_0 = \frac{2 B_{\rm ext}}{g_e \mu_B} }$

where ${\displaystyle \mu_B}$= 5.788 381 8060 x 10^-5 eV T^-1, and ${\displaystyle g_e}$= 2.002 319 304 362 56.

Related tags and articles

ISPIN, LNONCOLLINEAR