Exciton-phonon coupling and luminescence: Difference between revisions
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==BSE at finite momentum== | ==BSE at finite momentum== | ||
Go in the folder without symmetries, run the setup, perform the GW calculation if required from your system, and then run the BSE for all momentum '''q''' | Go in the folder without symmetries, run the setup, perform the GW calculation if required from your system, <br> and then run the BSE for all momentum '''q''' | ||
as explained in the tutorials: [http://www.yambo-code.org/wiki/index.php?title=How_to_obtain_an_optical_spectrum BSE basic], [http://www.yambo-code.org/wiki/index.php?title=How_to_choose_the_input_parameters BSE convergence], [http://www.yambo-code.org/wiki/index.php?title=How_to_treat_low_dimensional_systems BSE for 2D] | as explained in the tutorials: [http://www.yambo-code.org/wiki/index.php?title=How_to_obtain_an_optical_spectrum BSE basic], [http://www.yambo-code.org/wiki/index.php?title=How_to_choose_the_input_parameters BSE convergence], [http://www.yambo-code.org/wiki/index.php?title=How_to_treat_low_dimensional_systems BSE for 2D] | ||
Do not forget to turn on the flag <span style="color:red">WRbsWF</span> to write the excitonic wave-functions. | |||
== References == | == References == |
Revision as of 11:12, 21 February 2022
This tutorial works only with Yambo version > 6.x
The exciton-phonon part of Yambo does not support symmetries yet!!!
This an advanced tutorial, in order to calculate exciton-phonon coupling and phonon-assisted absorption/emission you need a deep knowledge of the theory and of the Yambo code.
In this tutorial we will calculate phonon-assisted absorption and luminescence including the scattering between exciton and phonon.[1][2][3]
We will consider as example bulk silicon. Notice that parameters of the present tutorial are not at convergence, but are just as a possible example.
The tutorial includes several steps and the calculations can be quite expensive.
Electron-phonon matrix elements
First of all we calculate electron-phonon matrix elements as explained in the section: Electron-phonon matrix elements but in the last passage of the tutorial we expand the electron-phonon matrix elements in all the Brillouin Zone. In order to do so, when we read the electron-phonon matrix elements from QE with the command ypp_ph -g g we turn on the flag GkkpExpand
gkkp # [R] gkkp databases gkkp_db # [R] GKKP database #GkkpReadBare # Read the bare gkkp DBsPATH= "../elph_dir/" # Path to the PW el-ph databases PHfreqF= "none" # PWscf format file containing the phonon frequencies PHmodeF= "none" # PWscf format file containing the phonon modes GkkpExpand # Expand the gkkp in the whole BZ #UseQindxB # Use qindx_B to expand gkkp (for testing purposes)
if everything worked fine in the log you will find:
.... <---> :: Uniform sampling :yes <---> :: Symmetry expanded :yes .....
Notice that in the calculation of the electron-phononn coupling you need a number of conduction bands as large as the one that will be used in the Bethe-Salpeter Equation.
Remove all symmetries
Now we remove all symmetries with the command ypp_ph -y
fixsyms # [R] Remove symmetries not consistent with an external perturbation
% Efield1
0.000000 | 0.000000 | 0.000000 | # First external Electric Field
%
% Efield2
0.000000 | 0.000000 | 0.000000 | # Additional external Electric Field
%
BField= 0.000000 T # [MAG] Magnetic field modulus
Bpsi= 0.000000 deg # [MAG] Magnetic field psi angle [degree]
Btheta= 0.000000 deg # [MAG] Magnetic field theta angle [degree]
RmAllSymm # Remove all symmetries
#RmTimeRev # Remove Time Reversal
#RmSpaceInv # Remove Spatial Inversion
#KeepKGrid # Do not expand the k-grid
the code will expand the electronic wave-function and copy the gkkp_expanded databases in the new folder.
BSE at finite momentum
Go in the folder without symmetries, run the setup, perform the GW calculation if required from your system,
and then run the BSE for all momentum q
as explained in the tutorials: BSE basic, BSE convergence, BSE for 2D
Do not forget to turn on the flag WRbsWF to write the excitonic wave-functions.
References
- ↑ Theory of phonon-assisted luminescence in solids: Application to hexagonal boron nitride, E. Cannuccia, B. Monserrat and C. Attaccalite, Phys. Rev. B 99, 081109(R) (2019)
- ↑ Exciton-Phonon Coupling in the Ultraviolet Absorption and Emission Spectra of Bulk Hexagonal Boron Nitride, F. Paleari et al. PRL 122, 187401(2019)
- ↑ Exciton-Phonon Interaction and Relaxation Times from First Principles, Hsiao-Yi Chen, Davide Sangalli, and Marco Bernardi,Phys. Rev. Lett. 125, 107401(2020)