Controlling quantum effects in enhanced strong-field ionisation with machine-learning techniques

Deep learning models have provided huge interpretation power for image-like data. Specifically, convolutional neural networks (CNNs) have demonstrated incredible acuity for tasks such as feature extraction or parameter estimation. Here we test CNNs on strong-field ionization photoelectron spectra, training on theoretical data sets to `invert' experimental data. Pulse characterization is used as a `testing ground', specifically we retrieve the laser intensity, where `traditional' measurements typically lead to 20% uncertainty. We report on crucial data augmentation techniques required to successfully train on theoretical data and return consistent results from experiments, including accounting for detector saturation. The same procedure can be repeated to apply CNNs in a range of scenarios for strong-field ionization. Using a predictive uncertainty estimation, reliable laser intensity uncertainties of a few percent can be extracted, which are consistently lower than those given by traditional techniques. Using interpretability methods can reveal parts of the distribution that are most sensitive to laser intensity, which can be directly associated with holographic interferences. The CNNs employed provide an accurate and convenient ways to extract parameters, and represent a novel interpretational tool for strong-field ionization spectra.

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Femtosecond pulse parameter estimation from photoelectron momenta using machine learning

Szołdra

Ciappina

Werby

et al. 2023

New J. Phys.

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Controlling quantum effects in enhanced strong-field ionisation with machine-learning techniques

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Femtosecond pulse parameter estimation from photoelectron momenta using machine learning

Femtosecond pulse parameter estimation from photoelectron momenta using machine learning

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