|
|
Line 75: |
Line 75: |
|
| |
|
| Additionally one needs to set {{TAG|ENMAX}} appropriately: | | Additionally one needs to set {{TAG|ENMAX}} appropriately: |
| {{TAG|ENMAX}} (>{{TAG|ENINI}}) needs to be chosen large enough so that the plane wave components of both the up-spinors as well as the components of the down-spinor all have | | {{TAG|ENMAX}} needs to be chosen larger than {{TAG|ENINI}}, and large enough so that the plane wave components of both the up-spinors as well as the components of the down-spinor all have a kinetic energy smaller than {{TAG|ENMAX}}. |
Revision as of 13:39, 6 July 2018
Generalized Bloch condition
Spin spirals may be conveniently modeled using a generalization of the Bloch condition (set LNONCOLLINEAR=.TRUE. and LSPIRAL=.TRUE.):
i.e., from one unit cell to the next the up- and down-spinors pick up an additional phase factor of and , respectively,
where R is a lattice vector of the crystalline lattice, and q is the so-called spin-spiral propagation vector.
The spin-spiral propagation vector is commonly chosen to lie within the first Brillouin zone of the reciprocal space lattice, and has to be specified by means of the QSPIRAL-tag.
The generalized Bloch condition above gives rise to the following behavior of the magnetization density:
This is schematically depicted in the figure at the top of this page:
the components of the magnization in the xy-plane rotate about the spin-spiral propagation vector q.
Basis set considerations
The generalized Bloch condition redefines the Bloch functions as follows:
This changes the Hamiltonian only minimally:
where in and the kinetic energy of a plane wave component changes to:
In the case of spin-spiral calculations the cutoff energy of the basis set is specified by means of the ENINI-tag.
Additionally one needs to set ENMAX appropriately:
ENMAX needs to be chosen larger than ENINI, and large enough so that the plane wave components of both the up-spinors as well as the components of the down-spinor all have a kinetic energy smaller than ENMAX.