Category:Constrained-random-phase approximation: Difference between revisions

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== Theoretical Background ==
== Theoretical Background ==
The constrained random phase approximation (CRPA) is a method that allows to calculate the effective interaction parameter U, J and J' for model Hamiltonians.  
The constrained random-phase approximation (CRPA) is a method that allows to calculate the effective interaction parameter U, J and J' for model Hamiltonians.  
The main idea is to neglect screening effects of specific '''target states''' in the screened Coulomb interaction W of the [[The GW approximation of Hedin's equations|GW method]].  
The main idea is to neglect screening effects of specific '''target states''' in the screened Coulomb interaction W of the [[The GW approximation of Hedin's equations|GW method]].  
The resulting partially screened Coulomb interaction is usually evaluated in a localized basis that spans the target space and is described by the model Hamiltonian.  
The resulting partially screened Coulomb interaction is usually evaluated in a localized basis that spans the target space and is described by the model Hamiltonian.  
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More information about CRPA is found on following page:
More information about CRPA is found on following page:


[[Constrained random phase approximation]]
[[Constrained random-phase approximation]]


== How to ==
== How to ==

Revision as of 06:58, 7 April 2022

All tags and articles that deal with CRPA calculations are members of this category.

Theoretical Background

The constrained random-phase approximation (CRPA) is a method that allows to calculate the effective interaction parameter U, J and J' for model Hamiltonians. The main idea is to neglect screening effects of specific target states in the screened Coulomb interaction W of the GW method. The resulting partially screened Coulomb interaction is usually evaluated in a localized basis that spans the target space and is described by the model Hamiltonian. The target space is usually low-dimensional and therefore allows for the application of a higher level theory, such as dynamical mean field theory.

More information about CRPA is found on following page:

Constrained random-phase approximation

How to


Pages in category "Constrained-random-phase approximation"

The following 7 pages are in this category, out of 7 total.