Category:Wannier functions: Difference between revisions

Latest revision as of 08:48, 20 August 2024

Wannier functions $|w_{m\mathbf {R} }\rangle$ are constructed by a linear combination of Bloch states $|\psi _{n\mathbf {k} }\rangle$ , i.e., the computed Kohn-Sham (KS) orbitals, as follows:

|w_{m\mathbf {R} }\rangle =\sum _{n\mathbf {k} }e^{-i\mathbf {k} \cdot \mathbf {R} }U_{mn\mathbf {k} }|\psi _{n\mathbf {k} }\rangle .

Here, $U_{mn\mathbf {k} }$ is a unitary matrix which can be generated using different approaches discussed below, $m$ is an index enumerating Wannier functions with position $\mathbf {R}$ , $n$ is the band index, and $\mathbf {k}$ is the Bloch vector. Generally, one starts with an initial guess for $U_{mn\mathbf {k} }$ that is built from $A_{mn\mathbf {k} }$ . The latter can be built from projections onto some localized-orbital basis.

Comprehensive instructions on how to construct Wannier orbitals in VASP can be found here.

One-shot singular-value decomposition (SVD)

In one-shot SVD, $A_{mn\mathbf {k} }$ is computed by projecting the KS orbitals onto localized orbitals basis $\phi _{m\mathbf {k} }$ that is specified by the LOCPROJ tag:

A_{mn\mathbf {k} }=\langle \psi _{n\mathbf {k} }|S|\phi _{m\mathbf {k} }\rangle ,

where

\phi _{i\mathbf {k} }(\mathbf {r} )=e^{\mathrm {i} \mathbf {k} \cdot \mathbf {r} }Y_{lm}({\hat {r}})R_{n}(r).

Note that $i$ encodes the quantum numbers $n$ , $l$ , and $m$ . Thus, in $A_{mn\mathbf {k} }$ , $m$ is not the magnetic quantum number.

Then, VASP performs one-shot SVD for each k point

A_{mn\mathbf {k} }=[D\Sigma V^{*}]_{mn\mathbf {k} }

to obtain the unitary matrix

U_{mn\mathbf {k} }=[DV^{*}]_{mn\mathbf {k} }.

Selected columns of the density matrix (SCDM)

The SCDM method ^[1] is switched on using LSCDM. It has the advantage that the specification of a local basis in terms of atomic quantum numbers is omitted.

Maximally localized Wannier functions using Wannier90

The interface of VASP with the Wannier90 code^[2]^[3] is mainly controlled by LWANNIER90 and LWANNIER90_RUN. First, the initial guess for $A_{mn\mathbf {k} }$ can be created by providing the projections block in the wannier90.win file (also see WANNIER90_WIN) and setting LWANNIER90=True.

In order to obtain maximally localized Wannier functions, $U_{mn\mathbf {k} }$ is constructed in a second step. For this, $A_{mn\mathbf {k} }$ could be created using any projection method in the first step, i.e., single-shot SVD method (LOCPROJ), SCDM method (LSCDM), or Wannier90 (LWANNIER90). Then, Wannier90 can be executed directly or through VASP with the LWANNIER90_RUN tag.

References

Pages in category "Wannier functions"

The following 19 pages are in this category, out of 19 total.

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KPOINTS WAN

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WANNIER90 WIN

[damle:mms:2018-1] A. Damle and L. Lin, Multiscale Model. Simul., 16(3), 1392–1410 (2018).

[mostofi:cpc:2014-2] A. A. Mostofi, J. R. Yates, G. Pizzi, Y.-S. Lee, I. Souza, D. Vanderbilt, and N. Marzari, An Updated Version of Wannier90: A Tool for Obtaining Maximally-Localised Wannier Functions, Computer Physics Communications 185, 2309 (2014).

[pizzi:jpcm:2020-3] G. Pizzi et al., Wannier90 as a community code: new features and applications, J. Phys.: Condens. Matter 32, 165902 (2020).

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+Wannier functions <math>|w_{m\mathbf{R}}\rangle</math> are constructed by a linear combination of Bloch states <math>|\psi_{n\mathbf{k}}\rangle</math>, i.e., the computed Kohn-Sham (KS) orbitals, as follows:
+::<math>
+|w_{m\mathbf{R}}\rangle =
+\sum_{n\mathbf{k}}
+e^{-i\mathbf{k}\cdot\mathbf{R}}
+U_{mn\mathbf{k}}
+|\psi_{n\mathbf{k}}\rangle.
+</math>
+Here, <math>U_{mn\mathbf{k}}</math> is a unitary matrix which can be generated using different approaches discussed below, <math>m</math> is an index enumerating Wannier functions with position <math>\mathbf{R}</math>, <math>n</math> is the band index, and <math>\mathbf{k}</math> is the Bloch vector.
+Generally, one starts with an initial guess for <math>U_{mn\mathbf{k}}</math> that is built from <math>A_{mn\mathbf{k}}</math>. The latter can be built from projections onto some localized-orbital basis.
+Comprehensive instructions on how to construct Wannier orbitals in VASP can be found [[Constructing_Wannier_orbitals|here]].
+== One-shot singular-value decomposition (SVD)==
+In one-shot SVD, <math>A_{mn\mathbf{k}}</math> is computed by projecting the KS orbitals onto localized orbitals basis <math>\phi_{m\mathbf{k}}</math> that is specified by the {{TAG|LOCPROJ}} tag:
+::<math>
+A_{mn\mathbf{k}} =
+\langle \psi_{n\mathbf{k}} | S |\phi_{m\mathbf{k}}\rangle,
+</math>
+where
+::<math>
+\phi_{i\mathbf{k}}(\mathbf{r}) = e^{\mathrm{i}\mathbf{k}\cdot\mathbf{r}} Y_{lm}(\hat{r})R_n(r).
+</math>
+Note that <math>i</math> encodes the quantum numbers <math>n</math>, <math>l</math>, and <math>m</math>. Thus, in <math>A_{mn\mathbf{k}}</math>, <math>m</math> is not the magnetic quantum number.
+Then, VASP performs one-shot SVD for each k point
+::<math>
+A_{mn\mathbf{k}} = [D \Sigma V^*]_{mn\mathbf{k}}
+</math>
+to obtain the unitary matrix
+::<math>
+U_{mn\mathbf{k}} = [DV^*]_{mn\mathbf{k}}.
+</math>
+== Selected columns of the density matrix (SCDM) ==
+The SCDM method {{cite|damle:mms:2018}} is switched on using {{TAG|LSCDM}}. It has the advantage that the specification of a local basis in terms of atomic quantum numbers is omitted.
+== Maximally localized Wannier functions using Wannier90 ==
+The interface of VASP with the Wannier90 code{{cite|mostofi:cpc:2014}}{{cite|pizzi:jpcm:2020}} is mainly controlled by {{TAG|LWANNIER90}} and {{TAG|LWANNIER90_RUN}}. First, the initial guess for <math>A_{mn\mathbf{k}}</math> can be created by providing the ''projections block'' in the '''wannier90.win''' file (also see {{TAG|WANNIER90_WIN}}) and setting {{TAG|LWANNIER90}}=True.
+In order to obtain maximally localized Wannier functions, <math>U_{mn\mathbf{k}}</math> is constructed in a second step. For this, <math>A_{mn\mathbf{k}}</math> could be created using any projection method in the first step, i.e., single-shot SVD method ({{TAG|LOCPROJ}}), SCDM method ({{TAG|LSCDM}}), or Wannier90 ({{TAG|LWANNIER90}}). Then, Wannier90 can be executed directly or through VASP with the {{TAG|LWANNIER90_RUN}} tag.
+== References ==
+<references/>
+[[Category:VASP|Wannier Functions]]