LSCRPA: Difference between revisions

Revision as of 09:17, 20 March 2026

LSCRPA = [logical]
Default: LSCRPA = .FALSE.

Description: LSCRPA selects the spectral-cRPA method.

Mind: Available as of VASP 6.6.0

In constrained random-phase approximation (cRPA) calculations, the target polarizability $\tilde{χ}$ is computed from the eigenspectrum of the target-space projectors as follows

{\tilde{χ}}_{{𝐆, 𝐆}^{'}}^{σ} (𝐪, i ω) \approx \frac{1}{N_{k}} \sum_{n n^{'} 𝐤} \frac{f_{n 𝐤} - f_{n^{'} 𝐤 - 𝐪}}{ϵ_{n 𝐤} - ϵ_{n^{'} 𝐤 - 𝐪} - i ω} θ_{n 𝐤}^{σ} θ_{n^{'} 𝐤 - 𝐩}^{σ^{'}} ⟨ u_{n 𝐤}^{σ} | e^{- i (𝐆 + 𝐪) 𝐫} | u_{n^{'} 𝐤 - 𝐪}^{σ^{'}} ⟩ ⟨ u_{n^{'} 𝐤 - 𝐪}^{σ^{'}} | e^{- i (𝐆^{'} - 𝐪) 𝐫^{'}} | u_{n^{'} 𝐤}^{σ} ⟩

Here $θ_{n 𝐤}^{σ}$ are the eigenvalues of the correlated projectors

$P_{m n}^{σ (𝐤)} = \sum_{i \in 𝒯} T_{i m}^{* σ (𝐤)} T_{i n}^{σ (𝐤)}$

ordered according to their leverage scores. The s-cRPA method results in larger effective interactions compared to w-cRPA or the projector-cRPA method and conserves the number of electrons.^[1]

References

↑ M. Kaltak, A. Hampel, M. Schlipf, I. R. Reddy, B. Kim and G. Kresse, Phys. Rev. B 112, 245102 (2025).

[kaltak:prb:2025-1] M. Kaltak, A. Hampel, M. Schlipf, I. R. Reddy, B. Kim and G. Kresse, Phys. Rev. B 112, 245102 (2025).

[1]

@@ Line 1: / Line 1: @@
 {{TAGDEF|LSCRPA|[logical]|.FALSE.}}
-Description: {{TAG|LSCRPA}} selects the [[Constrained–random-phase–approximation_formalism#Weighted_method|spectral cRPA method]].
+Description: {{TAG|LSCRPA}} selects the [[Constrained–random-phase–approximation_formalism#Spectral-cRPA_method_(s-cRPA)|spectral-cRPA method]].
-----
+{{Available|6.6.0}}
-{{NB|mind|Recommended cRPA method as of version 6.6.0.}}
+In constrained random-phase approximation (cRPA) calculations, the target polarizability <math>\tilde\chi</math> is computed from the eigenspectrum of the target-space projectors as follows
-When selected the spectral method in constrained RPA (cRPA) calculations is selected. The screening effects in the target space are calculated as follows
 ::<math>\tilde  \chi^\sigma_{{\bf G,G}'}({\bf q},i\omega)\approx
 \frac 1{N_k}\sum_{nn'{\bf k}}
@@ Line 25: / Line 24: @@
 \rangle
 </math>
-Here <math>\theta_{n{\bf k}}^\sigma</math> are the eigenvalues of the [[Constrained–random-phase–approximation_formalism#Projector_method|correlated projectors]]
+Here <math>\theta_{n{\bf k}}^\sigma</math> are the eigenvalues of the [[Constrained–random-phase–approximation_formalism#Projector-cRPA_method_(p-cRPA)|correlated projectors]]
 <math>
@@ Line 31: / Line 30: @@
 </math>
-ordered according to their leverage scores. The s-cRPA method results in larger effective interactions compared to [[Constrained–random-phase–approximation_formalism#Weighted_method|w-cRPA]] or the [[Constrained–random-phase–approximation_formalism#Projector_method|projector method]] and conserves the number of electrons.{{cite|kaltak:prb:2025}}
+ordered according to their leverage scores. The s-cRPA method results in larger effective interactions compared to [[Constrained–random-phase–approximation_formalism#Weighted-cRPA_method_(w-cRPA)|w-cRPA]] or the [[Constrained–random-phase–approximation_formalism#Projector-cRPA_method_(p-cRPA)|projector-cRPA method]] and conserves the number of electrons.{{cite|kaltak:prb:2025}}
-== Related tags and articles==
+== Related tags and articles ==
 {{TAG|LDISENTANGLED}},
 {{TAG|LWEIGHTED}},
@@ Line 41: / Line 40: @@
 == References ==
 <references/>
-----
 [[Category:INCAR_tag]][[Category:Constrained-random-phase approximation]]
-<!-- Link to categrories like this: [[Category:INCAR]][[Category:Constrained-random-phase approximation]] -->