We show a relation between fractional calculus and fractals, based only on physical and geometrical considerations. The link has been found in the physical origins of the power-laws, ruling the evolution of many natural phenomena, whose long memory and hereditary properties are mathematically modelled by differential operators of non integer order. Dealing with the relevant example of a viscous fluid seeping through a fractal shaped porous medium, we show that, once a physical phenomenon or process takes place on an underlying fractal geometry, then a power-law naturally comes up in ruling its evolution, whose order is related to the anomalous dimension of such geometry, as well as to the model used to describe the physics involved. By linearizing the non linear dependence of the response of the system at hand to a proper forcing action then, exploiting the Boltzmann superposition principle, a fractional differential equation is found, describing the dynamics of the system itself. The order of such equation is again related to the anomalous dimension of the underlying geometry. © 2014 Elsevier Inc.

Butera, S., Di Paola, M. (2014). A physically based connection between fractional calculus and fractal geometry. ANNALS OF PHYSICS, 350, 146-158 [10.1016/j.aop.2014.07.008].

A physically based connection between fractional calculus and fractal geometry

DI PAOLA, Mario
2014-01-01

Abstract

We show a relation between fractional calculus and fractals, based only on physical and geometrical considerations. The link has been found in the physical origins of the power-laws, ruling the evolution of many natural phenomena, whose long memory and hereditary properties are mathematically modelled by differential operators of non integer order. Dealing with the relevant example of a viscous fluid seeping through a fractal shaped porous medium, we show that, once a physical phenomenon or process takes place on an underlying fractal geometry, then a power-law naturally comes up in ruling its evolution, whose order is related to the anomalous dimension of such geometry, as well as to the model used to describe the physics involved. By linearizing the non linear dependence of the response of the system at hand to a proper forcing action then, exploiting the Boltzmann superposition principle, a fractional differential equation is found, describing the dynamics of the system itself. The order of such equation is again related to the anomalous dimension of the underlying geometry. © 2014 Elsevier Inc.
2014
Butera, S., Di Paola, M. (2014). A physically based connection between fractional calculus and fractal geometry. ANNALS OF PHYSICS, 350, 146-158 [10.1016/j.aop.2014.07.008].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10447/129801
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