Lithium
niobate is an excellent and widely used material for nonlinear
frequency conversion due to its strong optical nonlinearity and broad
transparency region. Here, we report the fabrication and experimental
investigation of resonant nonlinear metasurfaces for second-harmonic
generation based on thin-film lithium niobate. In the fabricated metasurfaces,
we observe pronounced Mie-type resonances leading to enhanced second-harmonic
generation in the direction normal to the metasurface. We find the
largest second-harmonic generation efficiency for the resonance dominated
by the electric contributions because its specific field distribution
enables the most efficient usage of the largest element of the lithium
niobate nonlinear susceptibility tensor. This is confirmed by polarization-resolved
second-harmonic measurements, where we study contributions from different
elements of the nonlinear susceptibility tensor to the total second-harmonic
signal. Our work facilitates establishing lithium niobate as a material
for resonant nanophotonics.
We report on second harmonic generation in a photonic crystal L3 cavity drilled in a thin self-suspended lithium niobate membrane. The cavity, resonant for the pump beam in the telecom wavelength range, exhibits a quality factor of around 500. Second harmonic generation has been measured with a low power continuous laser. A conversion efficiency of 6.4×10-9 has been estimated with an input coupled power of 53 µW
Nanoscale waveguides are basic building blocks of integrated optical devices. Especially, waveguides made from nonlinear optical materials, such as lithium niobate, allow access to a broad range of applications using second-order nonlinear frequency conversion processes. Based on a lithium niobate on insulator substrate, millimeter-long nanoscale waveguides were fabricated with widths as small as 200 nm. The fabrication was done by means of potassium hydroxide-assisted ion-beam-enhanced etching. The waveguides were optically characterized in the near infrared wavelength range showing phase-matched second-harmonic generation.
We report the first experimental observation of vortex light bullets that are discrete, spatiotemporal, solitary waves with orbital angular momentum. We analyze conditions for their existence and investigate their rich properties and dynamics. Vortex light bullets are excited in fiber arrays with spatially shaped femtosecond pulses and analyzed with a spatiotemporal cross correlator. Most importantly, we find that they have entirely new stability properties, being robust against considerable degrees of perturbation in a limited range of energies. All experimental findings are backed up by rigorous simulations, giving further insight into the rich dynamics of vortex light bullets.
We report on the light propagation in a one-line-defect photonic crystal waveguide (W1 PhC WG) patterned into a 450 nm thick free-standing lithium niobate membrane by ion-beam enhanced etching. The Bloch wave vectors and transmission spectrum of this PhC WG were retrieved from optical near-field images. The experimental data show good agreement with simulations performed with the three-dimensional (3D) finite-element method and the 3D finite-difference time-domain method. Those results are promising for the development of integrated optics devices operating at telecom wavelengths and based on free-standing lithium niobate PhC membranes.
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