Macroscopic Effects in Noncollinear High-Order Harmonic Generation

Abstract: We study two-color high-order harmonic generation using an intense driving field and its weak second harmonic, crossed under a small angle in the focus. Employing sum-and difference-frequency generation processes, such a noncollinear scheme can be used to measure and control macroscopic phase matching effects by utilizing a geometrical phase mismatch component, which depends on the noncollinear angle. We further show how spatial phase effects in the generation volume are mapped out into the far field allowing … Show more

“…Previous investigations of noncollinear HHG have shown that phase matching effects can determine the angle of preferential harmonic emission and used this angular dependence to infer the difference in the magnitude of the harmonic and driving laser wavevectors [43]. In this work, we experimentally and theoretically investigate the macroscopic physics of phasematched noncollinear HHG at high pressures.…”

“…Due to the angular separation between the driving laser beams, phase-matching in noncollinear HHG [41,43] is fundamentally different from either single-beam HHG or collinear HHG [3,24,[44][45][46][47] and presents both new challenges and new opportunities. Previous investigations of noncollinear HHG have shown that phase matching effects can determine the angle of preferential harmonic emission and used this angular dependence to infer the difference in the magnitude of the harmonic and driving laser wavevectors [43].…”

“…However, in a noncollinear geometry we must consider the projection of the driving laser wave vectors along the direction of the harmonic emission due to the angular differences between them (Fig. 1e-f) [28,43,[48][49][50]. This projection results in a modified phase-matching equation:…”

“…Typically, critical ionization places an upper limit on the laser intensities that can be used to drive HHG because at ionization levels above η c , the free-electron contribution to the index dominates, resulting in a driving laser phase velocity much greater than c [51,52]. Exceptions to this rule include quasi phase matching [53] or UV-driven HHG, where bright HHG beams can be produced through effective phase matching in multiply-ionized plasmas [43].…”

“…1i). Note that regardless of the specific conditions, the noncollinear phase mismatch varies as the cosine of the angular separation between the emitted harmonics and the driving lasers, which behaves quadratic in the small angle approximation [43] (see Appendix B, Fig. 6).…”

Phase matching of noncollinear sum and difference frequency high harmonic generation above and below the critical ionization level

“…Previous investigations of noncollinear HHG have shown that phase matching effects can determine the angle of preferential harmonic emission and used this angular dependence to infer the difference in the magnitude of the harmonic and driving laser wavevectors [43]. In this work, we experimentally and theoretically investigate the macroscopic physics of phasematched noncollinear HHG at high pressures.…”

“…Due to the angular separation between the driving laser beams, phase-matching in noncollinear HHG [41,43] is fundamentally different from either single-beam HHG or collinear HHG [3,24,[44][45][46][47] and presents both new challenges and new opportunities. Previous investigations of noncollinear HHG have shown that phase matching effects can determine the angle of preferential harmonic emission and used this angular dependence to infer the difference in the magnitude of the harmonic and driving laser wavevectors [43].…”

“…However, in a noncollinear geometry we must consider the projection of the driving laser wave vectors along the direction of the harmonic emission due to the angular differences between them (Fig. 1e-f) [28,43,[48][49][50]. This projection results in a modified phase-matching equation:…”

“…Typically, critical ionization places an upper limit on the laser intensities that can be used to drive HHG because at ionization levels above η c , the free-electron contribution to the index dominates, resulting in a driving laser phase velocity much greater than c [51,52]. Exceptions to this rule include quasi phase matching [53] or UV-driven HHG, where bright HHG beams can be produced through effective phase matching in multiply-ionized plasmas [43].…”

“…1i). Note that regardless of the specific conditions, the noncollinear phase mismatch varies as the cosine of the angular separation between the emitted harmonics and the driving lasers, which behaves quadratic in the small angle approximation [43] (see Appendix B, Fig. 6).…”

Phase matching of noncollinear sum and difference frequency high harmonic generation above and below the critical ionization level

Coherent Manipulation of Extreme-Ultraviolet Bessel Vortex Beams from Solids by Active Wavefront Shaping of Driving Fundamental Beams

In situ frequency gating and beam splitting of vacuum- and extreme-ultraviolet pulses