Control of the helicity of high-order harmonic radiation using bichromatic circularly polarized laser fields
Physical Review A, 2018•APS
High-order harmonic generation in two-color (ω− 2 ω) counter-rotating circularly polarized
laser fields opens the path to generate isolated attosecond pulses and attosecond pulse
trains with controlled ellipticity. The generated harmonics have alternating helicity, and the
ellipticity of the generated attosecond pulse depends sensitively on the relative intensities of
two adjacent, counter-rotating harmonic lines. For the s-type ground state, such as in helium,
the successive harmonics have nearly equal amplitude, yielding isolated attosecond pulses …
laser fields opens the path to generate isolated attosecond pulses and attosecond pulse
trains with controlled ellipticity. The generated harmonics have alternating helicity, and the
ellipticity of the generated attosecond pulse depends sensitively on the relative intensities of
two adjacent, counter-rotating harmonic lines. For the s-type ground state, such as in helium,
the successive harmonics have nearly equal amplitude, yielding isolated attosecond pulses …
High-order harmonic generation in two-color () counter-rotating circularly polarized laser fields opens the path to generate isolated attosecond pulses and attosecond pulse trains with controlled ellipticity. The generated harmonics have alternating helicity, and the ellipticity of the generated attosecond pulse depends sensitively on the relative intensities of two adjacent, counter-rotating harmonic lines. For the -type ground state, such as in helium, the successive harmonics have nearly equal amplitude, yielding isolated attosecond pulses and attosecond pulse trains with linear polarization, rotated by from pulse to pulse. In this work, we suggest a solution to overcome the limitation associated with the -type ground state. It is based on modifying the three propensity rules associated with the three steps of the harmonic generation process: ionization, propagation, and recombination. We control the first step by seeding high-order harmonic generation with XUV light tuned well below the ionization threshold, which generates virtual excitations with the angular momentum corotating with the field. We control the propagation step by increasing the intensity of the field relative to the field, further enhancing the chance of the field being absorbed versus the field, thus favoring the emission corotating with the seed and the field. We demonstrate our proposed control scheme using a helium atom as a target and solving a time-dependent Schrödinger equation in two and three dimensions.
American Physical Society
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