Scale-invariant nonlinear optics in gases

Heyl, C. M. and Coudert-Alteirac, H. and Miranda, M. and Louisy, M. and Kovács, Katalin and Valer, Tosa and Balogh, Emeric and Varjú, Katalin and L'Huillier, A. and Couairon, A. and Arnold, C. L. (2016) Scale-invariant nonlinear optics in gases. OPTICA, 3 (1). pp. 75-81. ISSN 2334-2536

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Abstract

Nonlinear optical methods are becoming ubiquitous in many areas of modern photonics. They are, however, often limited to a certain range of input parameters, such as pulse energy and average power, since restrictions arise from, for example, parasitic nonlinear effects, damage problems and geometrical considerations. Here, we show that many nonlinear optics phenomena in gaseous media are scale-invariant if spatial coordinates, gas density and laser pulse energy are scaled appropriately. We develop a general scaling model for (3+1)-dimensional wave equations, demonstrating the invari- ant scaling of nonlinear pulse propagation in gases. Our model is numerically applied to high-order harmonic generation and filamentation as well as experimentally verified using the example of pulse post-compression via filamentation. Our results provide a simple recipe for up-or downscaling of nonlinear processes in gases with numerous applications in many areas of science.

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