Erbe
Christine
Erbe
Christine
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ArticleAn International Quiet Ocean Experiment(Oceanography Society, 2011-06) Boyd, Ian L. ; Frisk, George V. ; Urban, Edward ; Tyack, Peter L. ; Ausubel, Jesse ; Seeyave, Sphie ; Cato, Doug ; Southall, Brandon L. ; Weise, Michael ; Andrew, Rex K. ; Akamatsu, Tomonari ; Dekeling, Rene ; Erbe, Christine ; Farmer, David M. ; Gentry, Roger ; Gross, Thomas F. ; Hawkins, Anthony D. ; Li, Fenghua ; Metcalf, Kathy ; Miller, James H. ; Moretti, David J. ; Rodrigo, Cristian ; Shinke, TomioThe effect of noise on marine life is one of the big unknowns of current marine science. Considerable evidence exists that the human contribution to ocean noise has increased during the past few decades: human noise has become the dominant component of marine noise in some regions, and noise is directly correlated with the increasing industrialization of the ocean. Sound is an important factor in the lives of many marine organisms, and theory and increasing observations suggest that human noise could be approaching levels at which negative effects on marine life may be occurring. Certain species already show symptoms of the effects of sound. Although some of these effects are acute and rare, chronic sublethal effects may be more prevalent, but are difficult to measure. We need to identify the thresholds of such effects for different species and be in a position to predict how increasing anthropogenic sound will add to the effects. To achieve such predictive capabilities, the Scientific Committee on Oceanic Research (SCOR) and the Partnership for Observation of the Global Oceans (POGO) are developing an International Quiet Ocean Experiment (IQOE), with the objective of coordinating the international research community to both quantify the ocean soundscape and examine the functional relationship between sound and the viability of key marine organisms. SCOR and POGO will convene an open science meeting to gather community input on the important research, observations, and modeling activities that should be included in IQOE.
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ArticleSounding the call for a global library of underwater biological sounds(Frontiers Media, 2022-02-08) Parsons, Miles J. G. ; Lin, Tzu-Hao ; Mooney, T. Aran ; Erbe, Christine ; Juanes, Francis ; Lammers, Marc O. ; Li, Songhai ; Linke, Simon ; Looby, Audrey ; Nedelec, Sophie L. ; Van Opzeeland, Ilse ; Radford, Craig A. ; Rice, Aaron N. ; Sayigh, Laela S. ; Stanley, Jenni A. ; Urban, Edward ; Di Iorio, LuciaAquatic environments encompass the world’s most extensive habitats, rich with sounds produced by a diversity of animals. Passive acoustic monitoring (PAM) is an increasingly accessible remote sensing technology that uses hydrophones to listen to the underwater world and represents an unprecedented, non-invasive method to monitor underwater environments. This information can assist in the delineation of biologically important areas via detection of sound-producing species or characterization of ecosystem type and condition, inferred from the acoustic properties of the local soundscape. At a time when worldwide biodiversity is in significant decline and underwater soundscapes are being altered as a result of anthropogenic impacts, there is a need to document, quantify, and understand biotic sound sources–potentially before they disappear. A significant step toward these goals is the development of a web-based, open-access platform that provides: (1) a reference library of known and unknown biological sound sources (by integrating and expanding existing libraries around the world); (2) a data repository portal for annotated and unannotated audio recordings of single sources and of soundscapes; (3) a training platform for artificial intelligence algorithms for signal detection and classification; and (4) a citizen science-based application for public users. Although individually, these resources are often met on regional and taxa-specific scales, many are not sustained and, collectively, an enduring global database with an integrated platform has not been realized. We discuss the benefits such a program can provide, previous calls for global data-sharing and reference libraries, and the challenges that need to be overcome to bring together bio- and ecoacousticians, bioinformaticians, propagation experts, web engineers, and signal processing specialists (e.g., artificial intelligence) with the necessary support and funding to build a sustainable and scalable platform that could address the needs of all contributors and stakeholders into the future.
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ArticleDoes rotation during echolocation increase the acoustic field of view? Comparative numerical models based on CT data of a live versus deceased dolphin(IOP Publishing, 2023-04-04) Wei, Chong ; Houser, Dorian ; Erbe, Christine ; Zhang, Chuang ; Matrai, Eszter ; Finneran, James J. ; Au, Whitlow W.Spinning is a natural and common dolphin behavior; however, its role in echolocation is unknown. We used computed tomography (CT) data of a live and a recently deceased bottlenose dolphin together with measurements of the acoustic properties of head tissues to perform acoustic property reconstrcution. The anatomical configuration and acoustic properties of the main forehead structures between the live and deceased dolphins were compared. Finite element analysis (FEA) was applied to simulate the generation and propagation of echolocation clicks, to compute their waveforms and spectra in both near- and far-fields, and to derive echolocation beam patterns. Model results from both the live and deceased dolphins were in good agreement with click recordings from live, echolocating individuals. FEA was also used to estimate the acoustic scene experienced by a dolphin rotating 180ã about its longitudinal axis to detect fish in the far-field at elevation angles of 0ã –20ã . The results suggest that the spinning behavior provides a wider insonification area and compensates for the dolphin’s relatively narrow biosonar beam and constraints on the pointing direction that are limited by head movement. The results also have implications for examining the accuracy of FEA in acoustic simulations using freshly deceased specimens.
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ArticleGlobal inventory of species categorized by known underwater sonifery(Nature Research, 2023-12-18) Looby, Audrey ; Erbe, Christine ; Bravo, Santiago ; Cox, Kieran ; Davies, Hailey L. ; Di Iorio, Lucia ; Jezequel, Youenn ; Juanes, Francis ; Martin, Charles W. ; Mooney, T. Aran ; Radford, Craig A. ; Reynolds, Laura K. ; Rice, Aaron N. ; Riera, Amalis ; Rountree, Rodney ; Spriel, Brittnie ; Stanley, Jenni A. ; Vela, Sarah ; Parsons, Miles J. G.A working group from the Global Library of Underwater Biological Sounds effort collaborated with the World Register of Marine Species (WoRMS) to create an inventory of species confirmed or expected to produce sound underwater. We used several existing inventories and additional literature searches to compile a dataset categorizing scientific knowledge of sonifery for 33,462 species and subspecies across marine mammals, other tetrapods, fishes, and invertebrates. We found 729 species documented as producing active and/or passive sounds under natural conditions, with another 21,911 species deemed likely to produce sounds based on evaluated taxonomic relationships. The dataset is available on both figshare and WoRMS where it can be regularly updated as new information becomes available. The data can also be integrated with other databases (e.g., SeaLifeBase, Global Biodiversity Information Facility) to advance future research on the distribution, evolution, ecology, management, and conservation of underwater soniferous species worldwide.