Two hydrodynamic effects are introduced in the standard transmission-line formalism, the focusing of the pressure and fluid velocity fields near the basilar membrane and the viscous damping at the fluid-basilar membrane interface, which significantly affect the cochlear response in the short-wave region. In this region, in which the wavelength is shorter than the cochlear duct height, only a layer of fluid of order of the wavelength is effectively involved in the traveling wave. This has been interpreted [8] as a reduced fluid contribution to the system inertia in the peak region, which is a viewpoint common to the 3-D FEM solutions. In this paper we propose an alternative approach, from a slightly different physical viewpoint. Invoking the fluid flux conservation along the traveling wave propagation direction, we can derive a rigorous propagation equation for the pressure integrated along the vertical axis. Consequently, the relation between the average pressure and the local pressure [4] at the fluid-BM interface can be written. The local pressure is amplified by a factor dependent on the local wavenumber with respect to the average pressure, a phenomenon we refer to as “fluid focusing”, which plays a relevant role in the BM total amplification gain. This interpretation of the hydrodynamic boost to the pressure provides a physical justification to the strategy [10] of fitting the BM admittance with a polynomial containing both a conjugated pole and a zero. In the short-wave region, the sharp gradients of the velocity field yield a second important effect, a damping force on the BM motion, proportional to the local wavenumber, which stabilizes active models and shifts the peak of the response towards the base, with respect to the resonant place. This way, the peaked BM response is not that of a proper resonance, corresponding to a sharp maximum of the admittance, but rather a focusing-driven growth toward the resonant place, which is “aborted” before reaching it by the sharply increasing viscous losses. The large values of the wavenumber that ensure strong focusing are ultimately fueled, against viscosity, by the nonlinear OHC mechanism, hence the otherwise puzzling observation of a wide nonlinear gain dynamics with almost level-independent admittance.
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27 February 2024
NONLINEARITY AND HEARING: ADVANCES IN THEORY AND EXPERIMENT: Proceedings of the 14th International Mechanics of Hearing Workshop
24–29 July 2022
Helsingør, Denmark
Research Article|
February 27 2024
Fluid focusing contributes to the BM vibration amplification by boosting the pressure
Renata Sisto;
Renata Sisto
a)
1
Department of Occupational and Environmental Medicine, Epidemiology and Hygiene, INAIL-National Research Centre for Safety and Prevention at Workplace
, Monteporzio Catone (Rome), ITALY
a)Corresponding author: r.sisto@inail.it
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Daniele Belardinelli;
Daniele Belardinelli
b)
1
Department of Occupational and Environmental Medicine, Epidemiology and Hygiene, INAIL-National Research Centre for Safety and Prevention at Workplace
, Monteporzio Catone (Rome), ITALY
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Alessandro Altoè;
Alessandro Altoè
c)
2
Caruso Department of Otolaryngology, University of Southern California
, Los Angeles, CA, USA
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Christopher A. Shera;
Christopher A. Shera
d)
2
Caruso Department of Otolaryngology, University of Southern California
, Los Angeles, CA, USA
3
Department of Physics and Astronomy, University of Southern California
, Los Angeles, CA, USA
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Arturo Moleti
Arturo Moleti
e)
4
Department of Physics and NAST Centre, University of Rome ‘Tor Vergata’
, Rome, ITALY
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AIP Conf. Proc. 3062, 020005 (2024)
Citation
Renata Sisto, Daniele Belardinelli, Alessandro Altoè, Christopher A. Shera, Arturo Moleti; Fluid focusing contributes to the BM vibration amplification by boosting the pressure. AIP Conf. Proc. 27 February 2024; 3062 (1): 020005. https://doi.org/10.1063/5.0189302
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