Clicking in a Killer Whale Habitat: Narrow-Band, High-Frequency Biosonar Clicks of Harbour Porpoise (Phocoena phocoena) and Dall’s Porpoise (Phocoenoides dalli)

Line A Kyhn,Kristian Beedholm,Jakob Tougaard,Rob Williams,Peter T Madsen,Frants H Jensen,Erin Ashe,Claude Wicker-Thomas

doi:10.1371/journal.pone.0063763

Line A Kyhn, Kristian Beedholm + Show 6 more

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https://doi.org/10.1371/journal.pone.0063763

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Journal: PloS one	Publication Date: May 28, 2013
Citations: 104	License type: CC BY 4.0

Affiliation: Aarhus University, University of St Andrews

Abstract

Odontocetes produce a range of different echolocation clicks but four groups in different families have converged on producing the same stereotyped narrow band high frequency (NBHF) click. In microchiropteran bats, sympatric species have evolved the use of different acoustic niches and subtly different echolocation signals to avoid competition among species. In this study, we examined whether similar adaptations are at play among sympatric porpoise species that use NBHF echolocation clicks. We used a six-element hydrophone array to record harbour and Dall’s porpoises in British Columbia (BC), Canada, and harbour porpoises in Denmark. The click source properties of all porpoise groups were remarkably similar and had an average directivity index of 25 dB. Yet there was a small, but consistent and significant 4 kHz difference in centroid frequency between sympatric Dall’s (137±3 kHz) and Canadian harbour porpoises (141±2 kHz). Danish harbour porpoise clicks (136±3 kHz) were more similar to Dall’s porpoise than to their conspecifics in Canada. We suggest that the spectral differences in echolocation clicks between the sympatric porpoises are consistent with evolution of a prezygotic isolating barrier (i.e., character displacement) to avoid hybridization of sympatric species. In practical terms, these spectral differences have immediate application to passive acoustic monitoring.

Highlights

Toothed whales have evolved the use of a suite of different sounds for communication and echolocation
Canadian Porpoises Porpoises were encountered in small groups of 3–8 animals and a total of 4.7 hours and 4.5 hours of recordings were obtained from several groups of Dall’s and harbour porpoises, respectively, over several days
Of the thousands of clicks recorded, 98 clicks from Dall’s porpoise were accepted as on-axis according to the five criteria and 78 of the British Columbia (BC) harbour porpoise clicks were classified as on-axis

Summary

Introduction

Toothed whales have evolved the use of a suite of different sounds for communication and echolocation. A functional biosonar system requires clicks of high source level to detect and classify prey at ranges that allow the animal to find sufficient food. Directionality is determined by the ratio between the size of the transmitting organ and the wavelength of the projected sound [2], [3] and small echolocating animals must use higher frequencies than larger species to achieve similar directionality [4], [5]. This appears to be generally true for echolocating toothed whales. There are, profound differences in echolocation clicks among different families of toothed whales, and among species within some families that are not a result of body size, but could be related to habitat or prey specializations instead

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