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High-harmonic spin-orbit angular momentum generation in crystalline solids preserving multiscale dynamical symmetry

Kohei Nagai, Takuya Okamoto, Yasushi Shinohara, Haruki Sanada, Katsuya Oguri

2024Science Advances15 citationsDOIOpen Access PDF

Abstract

Symmetries essentially provide conservation rules in nonlinear light-matter interactions and facilitate control and understanding of photon conversion processes or electron dynamics. Since anisotropic solids have rich symmetries, they are strong candidates for controlling both optical micro- and macroscale structures, namely, spin angular momentum (circular polarization) and orbital angular momentum (spiral wavefront), respectively. Here, we show structured high-harmonic generation linked to the anisotropic symmetry of a solid. By strategically preserving a dynamical symmetry arising from the spin-orbit interaction of light, we generate multiple orbital angular momentum states in high-order harmonics. The experimental results exhibit the total angular momentum conservation rule of light even in the extreme nonlinear region, which is evidence that the mechanism originates from a dynamical symmetry. Our study provides a deeper understanding of multiscale nonlinear optical phenomena and a general guideline for using electronic structures to control structured light, such as through Floquet engineering.

Topics & Concepts

Angular momentumPhysicsAngular momentum couplingOrbital angular momentum of lightClassical mechanicsTotal angular momentum quantum numberSymmetry (geometry)Angular momentum of lightOrbital motionOrbital angular momentum multiplexingHigh harmonic generationOptical vortexFloquet theoryNonlinear systemQuantum mechanicsLaserGeometryMathematicsOrbital Angular Momentum in OpticsLaser-Matter Interactions and ApplicationsAdvanced Fiber Laser Technologies
High-harmonic spin-orbit angular momentum generation in crystalline solids preserving multiscale dynamical symmetry | Litcius