How Loud Can you go? Physical and Physiological Constraints to Producing High Sound Pressures in Animal Vocalizations

Lasse Jakobsen,Jakob Christensen-Dalsgaard,Peter Møller Juhl,Coen P. H. Elemans

doi:10.3389/fevo.2021.657254

Lasse Jakobsen, Jakob Christensen-Dalsgaard + Show 2 more

Open Access

https://doi.org/10.3389/fevo.2021.657254

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Abstract

Sound is vital for communication and navigation across the animal kingdom and sound communication is unrivaled in accuracy and information richness over long distances both in air and water. The source level (SL) of the sound is a key factor in determining the range at which animals can communicate and the range at which echolocators can operate their biosonar. Here we compile, standardize and compare measurements of the loudest animals both in air and water. In air we find a remarkable similarity in the highest SLs produced across the different taxa. Within all taxa we find species that produce sound above 100 dBpeak re 20 μPa at 1 m, and a few bird and mammal species have SLs as high as 125 dBpeak re 20 μPa at 1 m. We next used pulsating sphere and piston models to estimate the maximum sound pressures generated in the radiated sound field. These data suggest that the loudest species within all taxa converge upon maximum pressures of 140–150 dBpeak re 20 μPa in air. In water, the toothed whales produce by far the loudest SLs up to 240 dBpeak re 1 μPa at 1 m. We discuss possible physical limitations to the production, radiation and propagation of high sound pressures. Furthermore, we discuss physiological limitations to the wide variety of sound generating mechanisms that have evolved in air and water of which many are still not well-understood or even unknown. We propose that in air, non-linear sound propagation forms a limit to producing louder sounds. While non-linear sound propagation may play a role in water as well, both sperm whale and pistol shrimp reach another physical limit of sound production, the cavitation limit in water. Taken together, our data suggests that both in air and water, animals evolved that produce sound so loud that they are pushing against physical rather than physiological limits of sound production, radiation and propagation.

Highlights

Sound is the medium through which animals, including humans, can communicate complicated and unambiguous signals: from laughter when we are happy, to terrified screaming when we fear for our lives
Because the reference value is typically 20 μPa in air and 1 μPa in water, the same absolute pressure in Pascal is represented by a numerical value 26 dB higher in water than in air when represented on the dB scale
Because it is not possible to measure the pressure at the location of the source, the source level (SL) is defined at some distance from the source

Summary

Introduction

Sound is the medium through which animals, including humans, can communicate complicated and unambiguous signals: from laughter when we are happy, to terrified screaming when we fear for our lives. Almost 10,000 bird species, 7,000 frog species, 6,000 mammal species, and an unknown number of fish and arthropod species, have evolved the ability to produce sounds, many with highly specialized organs (Bradbury and Vehrencamp, 2011), driven by complex motor patterns, and executed by exceptional muscles (Elemans et al, 2008, 2011; Mead et al, 2017). Sound plays a pivoting role in many behaviors, including courtship and territorial display signals in insects, fish, frogs, birds and mammals, and orientation and prey capture in echolocating animals. No other communication modality combines the accuracy, speed, and richness of communication over long distances as does sound, both in air and in water (Bradbury and Vehrencamp, 2011)

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