Bethe-Salpeter kernel
Prerequisites
Run Initialization
Run Static screening Run GW in PPA
Create the input
$ yambo -F 03_bse_Ws.in -b -o b -k sex -V qp -J 3D (for a 3D)
or
$ yambo -F 03_bse_Ws_2D.in -b -o b -k sex -V qp -r -J 2D (for a 2D)
Open it and change some input variables
First change BSEBands which specify the range of bands to be used in the construction of the BS kernel
For h-BN put:
% BSEBands 4 | 12 | # [BSK] Bands range
For h-BN 2D put:
% BSEBands 2 | 6 | # [BSK] Bands range
Then change the number of G-components (in number of RL or in energy cutoff) for the exchange(BSENGexx) and correlation (BSENGBlk) part of the BS kernel Both for h-BN or h-BN 2D put
BSENGexx= 30 Ry # [BSK] Exchange components BSENGBlk= 2 Ry # [BSK] Screened interaction block size
The GW energies are required in the excitonic hamiltonian.
If the rigid scissor assumption is a good approximation for the material of interest
the simplest way is to give the value of the minimum GW correction precalculated by you or found in the literature.
For hBN bulk:
% KfnQP_E value0000 | 1.000000 | 1.000000 | # [EXTQP BSK BSS] E parameters (c/v) eV|adim|adim
For hBN-2D:
% KfnQP_E value | 1.000000 | 1.000000 | # [EXTQP BSK BSS] E parameters (c/v) eV|adim|adim
Note that if you know also the values of the conduction and valence streachings you can insert them instead of using the default values of 1.
Instead if you have already generated a ndb.QP database for the full set of k-points and energies of the excitonic hamiltonian,
you can read it in this way
for hBN bulk:
KfnQPdb= " E < ./3D/ndb.QP " # [EXTQP BSK BSS] Database
for hBN-2D:
KfnQPdb= " E < ./2D/ndb.QP " # [EXTQP BSK BSS] Database
Close the input and run the code
$ yambo -F 03_bse_Ws.in -J 3D ( for 3D)
or
$ yambo -F 03_bse_Ws_2D.in -J 2D (for 2D)