This part of the code is quite recent and it is being actively developed, so not all the features might be available in the stable version.
Octopus can calculate dynamic polarizabilities and first-order hyperpolarizabilites in a linear-response scheme using the Sternheimer equation. It also possible to calculate optical spectra with this technique, but it is slower than time-evolution.
The first thing we will need for linear response is a Ground State calculation. Unlike other techniques, when using the Sterheimer equation you needn't do a unoccupied-states calculation. To improve the convergence of the linear-response calculation, it is better to use tightly converged wavefunctions. For example, you can add these parameters to your gs calculation:
EigenSolverFinalTolerance = 1e-10 ConvAbsDens = 1e-9
em_resp. The main parameter you have to specify is the frequency of the perturbation, given by the block. You can also add an imaginary part to the frequency by setting the variable . Adding a small imaginary part is required if you want to get the imaginary part of the polarizability or to calculate polarizabilities near resonance; a reasonable value is
To get the hyperpolarizabilties, you also have to specify the variablewith the three coefficients with respect to the base frequency; the three values must sum to zero.
After running, for each frequency in the input file, Octopus will generate a subdirectory under linear/. In each subdirectory there is a file called alpha that contains the real part of the polarizability tensor and the average polarizability
The imaginary part is written to file eta. If , there is also a file called cross_section_tensor that contains the photo-absorption cross section tensor for that frequency, related to the imaginary part of the polarizability ().
The hyperpolarizability will be in a file called beta at the base frequency, containing all the 27 components and some reduced quantities:
Optionally, Born charges can also be calculated.
In this mode only static polarizability can be obtained. The calculation is done by taking the numerical derivative of the energy with respect to an external static and uniform electric field. To use this, run with
=finite_differences. Octopus will run several ground-state energy calculations and then calculate the polarizability using a finite-differences formula for the derivative. The results will be in the em_resp_fd directory. Hyperpolarizability and Born charges can also be calculated.