Numerical Modelling of High Harmonic Generation in Gases
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Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Program
Modellbyggare
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Sammanfattning
High harmonic generation is a highly nonlinear phenomenon produced in high-intensity laser-matter
interactions, which results in the emission of wideband light in the extreme-ultraviolet or soft X-ray
spectrum. The emitted light consists of harmonics – spectral peaks at integer multiples of the frequency
of the driving laser. The intensity of the generated harmonics is approximately constant over
a wide range of frequencies, yielding a wideband spectrum and high frequency emission. The large
bandwidth together with the coherence of the emitted light leads to the generation of attosecond
duration pulses that have applications in measuring physical systems with ultrafast dynamics, such
as that of electrons in atoms and molecules.
Due to the highly nonlinear and quantum-mechanical nature of high harmonic generation, the theoretical
modeling of high harmonic generation must include single atomic responses in the presence of
laser light as well as nonlinear wave propagation equations. This requires numerical simulations in
order to calculate quantities relevant for experiments, such as conversion efficiency and the harmonic
spectrum.
In this work, a numerical simulation code called HarP has been developed to simulate high harmonic
generation in gases. The code utilizes the Crank-Nicolson numerical scheme to solve the wave propagation
equations and combines theoretical models and tabulated data for the microscopic response
of the atoms. This approach reduces computational cost compared with non-tabulated approaches
and complexity while maintaining accuracy. To validate HarP, benchmarks were performed against
another high-harmonic code utilizing a different methodology, as well as against established simulation
results from the literature. More specifically, these benchmarks focus on ionisation rates, pulse
profiles for different pressures and propagation lengths, and conversion efficiencies in argon. The
result demonstrates overall good agreement for ionisation, laser pulse propagation, and conversion
efficiency, with only minor differences observed.
Beskrivning
Ämne/nyckelord
High-harmonic generation, Numerical simulation, Attosecond Science
