Bethe-Salpeter solver: diagonalization: Difference between revisions
No edit summary |
|||
Line 66: | Line 66: | ||
The alternative of directly input corrections calculated from a previous GW calculation is shown in the [[Bethe-Salpeter on top of quasiparticle energies|next section]]. | The alternative of directly input corrections calculated from a previous GW calculation is shown in the [[Bethe-Salpeter on top of quasiparticle energies|next section]]. | ||
Important: if you wish to be able to analyse the exciton wave functions in the [[How to analyse excitons - CECAM 2021 school|postprocessing tutorial]], you must uncomment the following flag: | **Important**: if you wish to be able to analyse the exciton wave functions in the [[How to analyse excitons - CECAM 2021 school|postprocessing tutorial]], you must uncomment the following flag: | ||
WRbsWF # [BSS] Write to disk excitonic the WFs | WRbsWF # [BSS] Write to disk excitonic the WFs | ||
==Bethe-Salpeter solver runlevel== | ==Bethe-Salpeter solver runlevel== |
Revision as of 16:31, 24 March 2021
In this module you learn how to obtain an optical absorption spectra within the Bethe-Salpeter equation (BSE) framework by diagonalizing a previously calculated Bethe-Salpeter (BS) kernel.
Prerequisites
- You must first complete the Static screening and Bethe-Salpeter kernel modules
You will need:
- The
SAVE
databases for 3D hBN - The
3D_QP_BSE
directory (provided) which contains the database with the GW corrections (create one directory with this name and put the ndb.QP file produced yesterday there) - The
3D_BSE
directory containing the databases from the Static screening and Bethe-Salpeter kernel modules - The
yambo
executable gnuplot
for plotting spectra
Background
The macroscopic dielectric function (from which the absorption and EEL spectra can be computed) is obtained from the eigenvalues Eλ (excitonic energies) and eigenvectors Aλcvk (exciton composition in terms of electron-hole pairs) of the two-particle Hamiltonian:
To get the two-particle Hamiltonian eigensolutions you need to diagonalize the two-particle Hamiltonian (non spin-polarized case):
for which the 2V - W part was evaluated in the Bethe-Salpeter kernel module.
The difference of quasiparticle energies Δεcvk= εck - εvk is added to the matrix just before the solver. There are two possible choices:
- the Kohn-Sham energies (calculated at DFT level) are corrected through a Scissor and the renormalization of the conduction and valence bandwidth (linearly with respect to the conduction band minimum and the valence band maximum respectively):
Δεcvk= Mc(εckKS - CBM) - Mv(εvkKS - VBM) + Scissor
- the quasiparticle energies calculated at GW level are used (see next tutorial. Missing energies are computed by interpolation.
Choosing the input parameters
Invoke yambo with the "-y d" option in the command line:
$ yambo -F 03_3D_BSE_diago_solver.in -y d -V qp -J 3D_BSE
The input is open in the editor. The input variable to be changed are
% BEnRange 2.00000 | 8.00000 | eV % BEnSteps= 200
which define 200 evenly spaced points between 2 and 8 eV at which the spectrum is calculated (ω in the equation for the macroscopic dielectric function),
% BDmRange 0.10000 | 0.10000 | eV %
which defines the spectral broadening (Lorentzian model),
% BLongDir 1.000000 | 1.000000 | 0.000000 | %
which defines the direction of the perturbing electric field (in this case the in-plane direction).
Another parameter to modify is
% KfnQP_E 1.440000 | 1.000000 | 1.000000 | %
This gives the quasiparticle corrections to the Kohn-Sham eigenvalues and is deduced either from experiment or previous GW calculations. With reference to the equation in the Background, the format is
Scissor | Mc | Mv |
The alternative of directly input corrections calculated from a previous GW calculation is shown in the next section.
- Important**: if you wish to be able to analyse the exciton wave functions in the postprocessing tutorial, you must uncomment the following flag:
WRbsWF # [BSS] Write to disk excitonic the WFs
Bethe-Salpeter solver runlevel
$ yambo -F 03_3D_BSE_diago_solver.in -J 3D_BSE
In the log (either in standard output or in l-3D_BSE_optics_dipoles_bss_bse
), after various setup/loading, the BSE is diagonalized using the linked linear algebra libraries:
<---> [03] BSE solver(s) @q1 <---> [LA] SERIAL linear algebra <---> [03.01] Diago Solver @q1 <---> BSK diagonalize |########################################| [100%] --(E) --(X) <---> EPS R residuals |########################################| [100%] --(E) --(X) <---> BSK resp. funct |########################################| [100%] --(E) --(X)
The report r-3D_BSE_optics_dipoles_bss_bse
contains information relative to this runlevel in section 3:
[03] BSE solver(s) @q1 ======================
Take some time to inspect the log and the report to check the consistency with the input variables. This run produces a new database in the 3D_BSE directory
3D_BSE/ndb.BS_diago_Q01
So if you need the spectrum on a different energy range, direction, with a different broadening or on more points the diagonalization is not repeated, just the spectrum is recalculated. Note that this database, as well as any other netCDF-format database produced by yambo, can be directly accessed and read using python modules.
This run produces as well human readable files (o-*). Specifically o-3D_BSE.eps_q1_diago_bse
contains the real and imaginary part of the macroscopic dielectric function
$ less o-3D_BSE.eps_q1_diago_bse ... # # E/ev[1] EPS-Im[2] EPS-Re[3] EPSo-Im[4] EPSo-Re[5] # 2.00000 0.16162 5.83681 0.04959 4.14127 2.03015 0.16787 5.88612 0.05090 4.15638 ...
which is in the format
Energy in eV | Imaginary part BSE | Real part BSE |Imaginary part IPA | Real part IPA |
where real and imaginary parts refer to the macroscopic dielectric function. The imaginary part is related to the optical absorption. The latter (column 2) can be plotted versus the photon energy (column 1) and compared with the independent particle approximation (IPA, column 4), e.g.:
$ gnuplot ... plot 'o-3D_BSE.eps_q1_diago_bse' u 1:2 w l t 'BSE', 'o-3D_BSE.eps_q1_diago_bse' u 1:4 w l t 'IPA'
The addition of the kernel has the effect to red-shift the spectrum onset and to redistribute the oscillator strengths. Note that the convergence with respect to k-points smooths out the low energy peaks in the IPA (which are an artifact of poor convergence with k-points producing an artificial confinement) to give the shoulder corresponding to the van Hove singularity in the band structure. On the other hand the low energy peak in the BSE is genuine and it is the signature of a bound exciton.
Summary
From this tutorial you've learned:
- How to compute the optical spectrum by using the diagonal solver within the Bethe-Salpeter equation framework
Links
- Previous module: Bethe-Salpeter kernel
- Next module: Bethe-Salpeter on top of quasiparticle energies
- Alternative Bethe-Salpeter equation solver: Lanczos-Haydock
- Alternative Bethe-Salpeter equation solver: Slepc
- Exciton analysis: How to analyse excitons - CECAM 2021 school
- Back to Calculating optical spectra including excitonic effects: a step-by-step guide tutorial
- Back to tutorials menu
- Back to technical modules menu