posted on 2024-12-13, 17:00authored byV. A. Antonov, I. R. Khairulin, M. Yu. Emelin, M. M. Popova, E. V. Gryzlova, M. Yu. Ryabikin
It is shown that under optimal conditions, the generation of the 3rd, 5th, 7th, and 9th harmonics of the short-wave laser field by helium atoms is mainly due to transitions between bound states, and the maximum energy of the harmonics is achieved under conditions of their resonant mul-tiphoton excitation. In this case, the optima for the generation of the 3rd, 5th, 7th, and 9th har-monics of the field correspond to three-, four-, five-, and six-photon resonances, and the optimal value of the peak field intensity, depending on the harmonic order, varies from 2.5*10^14 W/cm^2 to 1.2*10^15 W/cm^2. The total probability of excitation and ionization of an atom at the end of a laser pulse under appropriate conditions exceeds 1/2. With such intensity and not-too-high fre-quency of the laser field, the Stark effect turns out to be very significant, which allows it to be tuned into resonance with an arbitrary excited state of the atom by changing the intensity of the field without changing its frequency. It is shown that for the laser field parameters maximizing the energy of the Nth harmonic, N from 3 to 9, this harmonic dominates in the dipole acceleration spectrum. At the same time, the amplitudes of the remaining harmonics increase as the harmonic order approaches N. In particular, under the conditions maximizing the yield of the 9th harmon-ic, the harmonic amplitudes increase when moving from the 3rd harmonic to the 5th and then to the 7th and 9th harmonics. At the same time, under the conditions maximizing the yield of the 3rd harmonic, its amplitude in the dipole acceleration spectrum exceeds not only the amplitudes of the other harmonics, but also the amplitude of the atomic response at the frequency of the driving field.
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