Two-photon absorption: Difference between revisions

In this tutorial we will show how to calculate two-photon absorption(TPA) in bulk silicon, following the approach descried in Ref. ^[1].
In this tutorial we suppose you are already familiar with the non-linear response using the Yambo code.
If it is not the case please study the previous tutorials: Linear response using Dynamical Berry Phase and Real time approach to non-linear response (SHG).

The tutorial is divided in different steps from the DFT calculation to the final TPA spectrum. For the calculation of the TPA we will use the real-time approach proposed in Ref. ^[2]

DFT calculations

Here we provide input files for QuantumEspresso both the self-consistent calculation and the non-self-consistent: QE_silicon.tgz
Run them, import the wave-function in Yambo and run the setup. (see previous tutorials).

Removing symmetries

In this tutorial we will calculate the TPA along the 'x' direction therefore we remove symmetries not compatible with an external field along this direction, with the command ypp_nl -y:

fixsyms                          # [R] Remove symmetries not consistent with an 
external perturbation
% Efield1
  1.000000 | 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

the you can go in the FixSymm folder and run the setup again.

Calculations at different field intensities

In order to extract the TPA coefficient we will run a series of simulation at different intensities of the external field: Ε, Ε/2, Ε/4. The polarization obtained from these simulation can be expanded in the field as:

then we will combine them to obtain the TPA coefficient as:

for more detail see Ref.^[1]. Hereafter the inputs for the real-time simulation. These inputs can be generated using the command yambo -u n -V qp. The first input that we will callinput1.in reads:

nloptics                         # [R] Non-linear spectroscopy
% NLBands
   1 | 7 |                           # [NL] Bands range
%
NLverbosity= "low"               # [NL] Verbosity level (low | high)
NLtime=74.000000           fs    # [NL] Simulation Time
NLstep= 0.002500           fs    # [NL] Time step length
NLintegrator= "INVINT"           # [NL] Integrator ("EULEREXP/RK2/RK4/RK2EXP/HEUN/INVINT/CRANKNIC")
NLCorrelation= "IPA"             # [NL] Correlation ("IPA/HARTREE/TDDFT/LRC/LRW/JGM/SEX")
NLLrcAlpha= 0.000000             # [NL] Long Range Correction
% NLEnRange
  0.200000 | 5.000000 |         eV    # [NL] Energy range
%
NLEnSteps= 24                   # [NL] Energy steps
NLDamping= 0.100000        eV    # [NL] Damping (or dephasing)
#EvalCurrent                   # [NL] Evaluate the current
% Field1_Dir
   1.000000 | 0.000000 | 0.000000 |        # [NL Field1] Field Versor
%
Field1_kind= "SIN"             # [NL Field1] Kind(SIN|SOFTSIN|RES|ANTIRES|GAUSS|DELTA|QSSIN)
% GfnQP_E
 0.600000 | 1.000000 | 1.000000 |        # [EXTQP G] E parameters  (c/v) eV|adim|adim
%
Field1_Int=4.0000E+4         kWLm2 # [NL Field1] Intensity 
Field1_Tstart= 0.000000      fs    # [NL Field1] Initial Time

the second and third input files (input2.in and input3.in) are equivalent to the first one but with different field intensities: Field1_Int=1.0000E+4 and Field1_Int=0.2500E+4/

Then you can run the three simulations with the command:

yambo -J input1.in -J RUN1
yambo -J input2.in -J RUN2
yambo -J input3.in -J RUN3

Use Richardson extrapolation to extract the TPA

Now we use the formula:

to combine the different polarization and extract the TPA coefficient. This can be done using the following script:

References