Renormalisation group theory applied to x+x+x2=0
Abstract
The titular ordinary differential equation (ODE) is encountered in the theory of on-axis inertial particle capture by a blunt stationary collector at a viscous-flow stagnation point. Phase space for the ODE divides into two attractor basins, representing particle trajectories which do or do not collide with the collector in a finite time. Written as x + x + ε x2 = 0, we formulate the renormalisation group (RG) amplitude equations for this problem and argue that the critical trajectory which separates the attractor basins corresponds to a trivial but exact solution of these, and can therefore be extracted as a power series in ε. We show how this can be used to find the cross-over between capture and non-capture as a function of distance from the stagnation point, for a particle released into the flow with no initial acceleration. This cross-over, previously only computable by numerical integration of the ODE, can therefore be expressed as a (numerically) convergent series with rational terms.
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