Stefano Cerbelli scite author profile

This article addresses the scaling and spectral properties of the advection–diffusion equation in closed two-dimensional steady flows. We show that homogenization dynamics in simple model flows is equivalent to a Schrödinger eigenvalue problem in the presence of an imaginary potential. Several properties follow from this formulation: spectral invariance, eigenfunction localization, and a universal scaling of the dominant eigenvalue with respect to the Péclet number $\mbox{\it Pe}$. The latter property means that, in the high-$\mbox{\it Pe}$ range (in practice $\mbox{\it Pe},\geq 10^2 \hbox{--} 10^3$), the scaling exponent controlling the behaviour of the dominant eigenvalue with the Péclet number depends on the local behaviour of the potential near the critical points (local maxima/minima). A kinematic interpretation of this result is also addressed.

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The intermaterial area density generated by time- and spatially periodic 2D chaotic flows

Muzzio

Álvarez

Cerbelli

et al. 2000

Chemical Engineering Science

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The geometry of mixing in time-periodic chaotic flows. I. Asymptotic directionality in physically realizable flows and global invariant properties

Giona¹,

Adrover²,

Muzzio

et al. 1999

Physica D: Nonlinear Phenomena

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