Abdulah S. Jašarević scite author profile

The quantum-mechanical transition amplitude of an ionization process induced by a strong laser field is typically expressed in the form of an integral over the ionization time of a highly oscillatory function. Within the saddle-point (SP) approximation this integral can be represented by a sum over the contributions of the solutions of the SP equation for complex ionization time. It is shown that, for the general case of an elliptically polarized polychromatic laser field, these solutions can be obtained as zeros of a trigonometric polynomial of the order n and that there are exactly n relevant solutions, which are to be included in the sum. The results obtained are illustrated by examples of various tailored laser fields that are presently used in strong-field physics and attoscience. For some critical values of the parameters two SP solutions can coalesce and the topology of the 'steepest descent' integration contour changes so that some SPs are bypassed. Around the critical parameters a uniform approximation should be used instead of the SP method.

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Ionization by a strong orthogonal two-color laser field: a quantum-orbit-theory approach

Jašarević

Hasović

Milošević

2022

Eur. Phys. J. D

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High-Order Above-Threshold Ionization Using a Bi-Elliptic Orthogonal Two-Color Laser Field with Optimal Field Parameters

Jašarević

Hasović

Milošević

2023

Atoms

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In the present paper, we study the high-order above-threshold ionization of noble-gas atoms using a bi-elliptic orthogonal two-color (BEOTC) field. We give an overview of the SFA theory and calculate the differential ionization rate for various values of the laser field parameters. We show that the ionization rate strongly depends on the ellipticity and the relative phase between two field components. Using numerical optimization, we find the values of ellipticity and relative phase that maximize the ionization rate at energies close to the cutoff energy. To explain the obtained results, we present, to the best of our knowledge, for the first time the quantum-orbit analysis in the BEOTC field. We find and classify the saddle-point (SP) solutions and study their contributions to the total ionization rate. We analyze quantum orbits and corresponding velocities to explain the contribution of relevant SP solutions.

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Modified saddle-point method applied to direct ionization of noble gas atoms

Jašarević

Hasović

Milošević

2023

J. Phys. A: Math. Theor.

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When exposed to strong laser ﬁelds, atoms or molecules can absorb more photons from the laser ﬁeld than is necessary for ionization. This process is called above-threshold ionization (ATI). In analyzing this process, the strong-ﬁeld approximation (SFA) turns out to be a very useful theoretical tool. In the SFA the diﬀerential ionization rate, which is an observable quantity, can be expressed as an integral over the ionization time and can be calculated by numerical integration (NI) or using the saddle-point method (SPM). When we use the Slater orbitals to describe the ground-state wave function of the valence electron, the results obtained using the SPM and NI do not agree. We ﬁnd the reasons for this disagreement and introduce a modiﬁed SPM that leads to excellent agreement between the SPM and NI results for various strong laser ﬁelds.

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Povratak duha evropskog humanizma / The Return of the Spirit of European Humanism

Jašarević

2022

pregled

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