Abstract
This research investigates laser-induced convection through a stream function-vorticity formulation. Specifically, this paper considers a solution to the steady Boussinesq NavierâStokes equations in two dimensions with a slip boundary condition on a finite box. A fixed-point algorithm is introduced in stream function-vorticity variables, followed by a proof of the existence of steady solutions for small laser amplitudes. From this analysis, an asymptotic relationship is demonstrated between the nondimensional fluid parameters and least upper bounds for laser amplitudes that guarantee existence, which accords with numerical results implementing the algorithm in a finite difference scheme. The findings indicate that the upper bound for laser amplitude scales by O(Reâ2Peâ1Riâ1) when Reâ«Pe, and by O(Reâ1Peâ2Riâ1) when Peâ«Re. These results suggest that the existence of steady solutions is heavily dependent on the size of the Reynolds (Re) and Peclet (Pe) numbers, as noted in previous studies. The simulations of steady solutions indicate the presence of symmetric vortex rings, which agrees with experimental results described in the literature. From these results, relevant implications to thermal blooming in laser propagation simulations are discussed.
Highlights
In this article, we investigate steady Boussinesq fluid convection driven by a laser source
This study considered the existence of solutions to a 2D steady, Boussinesq fluid flow problem in a stream function-vorticity formulation
Motivated by the fact that thermal blooming often plays an immense role in the simulation of laser propagation, the algorithm introduced in this paper provides a rapid numerical method for computing the steady-state of a buoyancy driven fluid while heated by a laser
Summary
We investigate steady Boussinesq fluid convection driven by a laser source. We discuss the relationship between the physical problem and the stream functionvorticity representation, we introduce and prove convergence of an iteration to solve the Boussinesq NavierâStokes equations, and we conclude with results and a discussion on the asymptotic scaling of nondimensional fluid parameters with respect to convergence. Following this analysis, we provide numerical solutions to the steady-state and we examine the applications to laser beam propagation
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
