Impulse Response Function for Brownian Motion

Abstract

Motivated from the central role of the mean-square displacement and its second time-derivative -- that is the velocity autocorrelation function v(0)v(t)=12 d2 r2 (t)dt2 in the description of Brownian motion, we revisit the physical meaning of the first time-derivative of the mean-square displacement of Brownian particles. By employing a rheological analogue for Brownian motion, we show that the time-derivative of the mean-square displacement d r2 (t) dt of Brownian microspheres with mass m and radius R immersed in any linear, isotropic viscoelastic material is identical to N KB T3 π Rh(t), where h(t) is the impulse response function of a rheological network that is a parallel connection of the linear viscoelastic material with an inerter with distributed inertance mR=m6 π R. The impulse response function h(t)=3π RN KB Td r2 (t) dt of the viscoelastic material-inerter parallel connection derived in this paper at the stress-strain level of the rheological analogue is essentially the response function (t)=h(t)6π R of the Brownian particles expressed at the force-displacement level by Nishi et al. (2018). By employing the viscoelastic material-inerter rheological analogue we derive the mean-square displacement and its time-derivatives of Brownian particles immersed in a viscoelastic material described with a Maxwell element connected in parallel with a dashpot which captures the high-frequency viscous behavior and we show that for Brownian motion in such fluid-like soft matter the impulse response function, h(t) maintains a finite constant value in the long term.