Pump and Probe
This tutorial works only with Yambo version > 5.2, that will be released soon.
In this tutorial we will show you how to setup two external fields in yambo_nl, to perform pump and probe simulation. At present this tutorial explain only how to run simulation and obtain the final polarization. We are working on python script to analyze results that will be make available soon.
We start from the AlAs wave-functions of the Real time approach to non-linear response tutorial and remove symmetries according to the Pump and Probe external fields as explained in the Prerequisites for Real Time propagation with Yambo.
In our example we choose direction [1,1,0] for the pump and [0,0,1] for the probe, the corresponding ypp.in file will be:
fixsyms # [R] Remove symmetries not consistent with an external perturbation % Efield1 1.000000 | 1.000000 | 0.000000 | # First external Electric Field % % Efield2 0.000000 | 0.000000 | 1.000000 | # 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
then we generate the Pump&Probe input with the command yambo_nl -u p -V rt:
nloptics # [R] Non-linear spectroscopy DIP_Threads=0 # [OPENMP/X] Number of threads for dipoles NL_Threads=0 # [OPENMP/NL] Number of threads for nl-optics % NLBands 3 | 6 | # [NL] Bands range % NLverbosity= "high" # [NL] Verbosity level (low | high) NLstep= 0.010000 fs # [NL] Time step length NLtime= 75.0000 fs # [NL] Simulation Time 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 NLDamping= 0.100000 eV # [NL] Damping (or dephasing) RADLifeTime= 15.00000 fs # [RT] Radiative life-time (if negative Yambo sets it equal to Phase_LifeTime in NL) #UseDipoles # [NL] Use Covariant Dipoles (just for test purpose) #FrSndOrd # [NL] Force second order in Covariant Dipoles #EvalCurrent # [NL] Evaluate the current HARRLvcs= 10417 RL # [HA] Hartree RL components EXXRLvcs= 10417 RL # [XX] Exchange RL components % ExtF_Dir 1.000000 | 1.000000 | 0.000000 | # [NL ExtF] Field Versor % % ExtF_Freq 1.500000 | 1.500000 | eV # [NL ExtF] Field Frequency % ExtF_Int= 1000.00 kWLm2 # [NL ExtF] Field Intensity ExtF_Width= 5.00000 fs # [NL ExtF] Field Width ExtF_kind= "QSSIN" # [NL ExtF] Kind(SIN|SOFTSIN|RES|ANTIRES|GAUSS|DELTA|QSSIN) ExtF_Tstart= 0.010000 fs # [NL ExtF] Initial Time % ExtF2_Dir 0.000000 | 0.000000 | 1.000000 | # [NL ExtF] Field Versor % % ExtF2_Freq 0.100000 | 0.100000 | eV # [NL ExtF] Field Frequency % ExtF2_Int= 10.0000 kWLm2 # [NL ExtF] Field Intensity ExtF2_Width= 0.000000 fs # [NL ExtF] Field Width ExtF2_kind= "DELTA" # [NL ExtF] Kind(SIN|SOFTSIN|RES|ANTIRES|GAUSS|DELTA|QSSIN) ExtF2_Tstart= 30.00000 fs # [NL ExtF] Initial Time
In this simulation we set a dephasing of 0.1 eV and a radiative life-time of 15 fs, The two external field are a sinus with frequency 1.5 eV convoluted with a Guassian of width 5 fs with and intensity of 1000 KW/cm-2, and then a delta function that starts at 30 fs with an intensity of 10 KW/cm-2. Below we plot the corresponding total electric field in the x and z direction and the polarization in the same directions: