Your search keyword '"DelWayne R. Bohnenstiehl"' showing total 13 results

1. Correction: Oyster Larvae Settle in Response to Habitat-Associated Underwater Sounds.

Author

Ashlee Lillis, David B. Eggleston, and DelWayne R. Bohnenstiehl

Subjects

Medicine, Science

Published

2014

2. Hurricane impacts on a coral reef soundscape

Author

David B. Eggleston, Kayelyn R. Simmons, and DelWayne R. Bohnenstiehl

Subjects

Atmospheric Science, Coral reef fish, Marine and Aquatic Sciences, Social Sciences, Reef Ecosystems, Geographical locations, Crustacea, Psychology, Sound pressure, Multidisciplinary, geography.geographical_feature_category, Animal Behavior, Ecology, Soundscape ecology, Coral Reefs, Cyclonic Storms, Physics, Fishes, Coral reef, Oceanography, Crepuscular, Sound, Physical Sciences, Florida, Medicine, Sound Pressure, Research Article, Soundscape, Storms, Science, Marine Biology, Ecosystems, Meteorology, Animals, Reef, Ecosystem, geography, Behavior, Ecology and Environmental Sciences, Biology and Life Sciences, Correction, Storm, Acoustics, United States, North America, Earth Sciences, Reefs, Environmental science, People and places, Bioacoustics, Zoology

Abstract

Soundscape ecology is an emerging field in both terrestrial and aquatic ecosystems, and provides a powerful approach for assessing habitat quality and the ecological response of sound-producing species to natural and anthropogenic perturbations. Little is known of how underwater soundscapes respond during and after severe episodic disturbances, such as hurricanes. This study addresses the impacts of Hurricane Irma on the coral reef soundscape at two spur-and-groove fore-reef sites within the Florida Keys USA, using passive acoustic data collected before and during the storm at Western Dry Rocks (WDR) and before, during and after the storm at Eastern Sambo (ESB). As the storm passed, the cumulative acoustic exposure near the seabed at these sites was comparable to a small vessel operating continuously overhead for 1–2 weeks. Before the storm, sound pressure levels (SPLs) showed a distinct pattern of low frequency diel variation and increased high frequency sound during crepuscular periods. The low frequency band was partitioned in two groups representative of soniferous reef fish, whereas the high frequency band represented snapping shrimp sound production. Daily daytime patterns in low-frequency sound production largely persisted in the weeks following the hurricane. Crepuscular sound production by snapping shrimp was maintained post-hurricane with only a small shift (~1.5dB) in the level of daytime vs nighttime sound production for this high frequency band. This study suggests that on short time scales, temporal patterns in the coral reef soundscape were relatively resilient to acoustic energy exposure during the storm, as well as changes in the benthic habitat and environmental conditions resulting from hurricane damage.

Published

2021

3. Correction: Hurricane impacts on a coral reef soundscape

Author

David B. Eggleston, DelWayne R. Bohnenstiehl, and Kayelyn R. Simmons

Subjects

Soundscape, Multidisciplinary, Geography, geography.geographical_feature_category, Oceanography, Science, Medicine, Coral reef

Abstract

[This corrects the article DOI: 10.1371/journal.pone.0244599.].

Published

2021

4. Oyster toadfish (Opsanus tau) boatwhistle call detection and patterns within a large-scale oyster restoration site

Author

David B. Eggleston, DelWayne R. Bohnenstiehl, R. Patrick Lyon, M. Lisa Kellogg, and Shannon W. Ricci

Subjects

0106 biological sciences, Oyster toadfish, Sexual Reproduction, Oyster, Sound Spectrography, Marine and Aquatic Sciences, lcsh:Medicine, Crabs, 01 natural sciences, Pattern Recognition, Automated, Oysters, Opsanus, Water Quality, lcsh:Science, Mammals, Multidisciplinary, geography.geographical_feature_category, biology, Physics, Temperature, Animal Models, Scale (music), Crustaceans, Experimental Organism Systems, Physical Sciences, Vertebrates, Rabbits, Research Article, Bivalves, Conservation of Natural Resources, Spawning, Arthropoda, Photoperiod, Modes of Reproduction, Research and Analysis Methods, 010603 evolutionary biology, biology.animal, Mating call, Circadian Clocks, Animals, Seawater, 14. Life underwater, Reef, Toadfish, Ecosystem, geography, Maryland, 010604 marine biology & hydrobiology, Significant difference, Ecology and Environmental Sciences, lcsh:R, Organisms, Biology and Life Sciences, Molluscs, Acoustics, biology.organism_classification, Batrachoidiformes, Invertebrates, Sunrise, Ostreidae, Fishery, Amniotes, Earth Sciences, Reefs, Environmental science, Daylight, lcsh:Q, Vocalization, Animal, Chronobiology, Developmental Biology

Abstract

During May 2015, passive acoustic recorders were deployed at eight subtidal oyster reefs within Harris Creek Oyster Sanctuary in Chesapeake Bay, Maryland USA. These sites were selected to represent both restored and unrestored habitats having a range of oyster densities. Throughout the survey, the soundscape within Harris Creek was dominated by the boatwhistle calls of the oyster toadfish, Opsanus tau. A novel, multi-kernel spectral correlation approach was developed to automatically detect these boatwhistle calls using their two lowest harmonic bands. The results provided quantitative information on how call rate and call frequency varied in space and time. Toadfish boatwhistle fundamental frequency ranged from 140 Hz to 260 Hz and was well correlated (r = 0.94) with changes in water temperature, with the fundamental frequency increasing by ~11 Hz for every 1°C increase in temperature. The boatwhistle call rate increased from just a few calls per minute at the start of monitoring on May 7th to ~100 calls/min on May 10th and remained elevated throughout the survey. As male toadfish are known to generate boatwhistles to attract mates, this rapid increase in call rate was interpreted to mark the onset of spring spawning behavior. Call rate was not modulated by water temperature, but showed a consistent diurnal pattern, with a sharp decrease in rate just before sunrise and a peak just after sunset. There was a significant difference in call rate between restored and unrestored reefs, with restored sites having nearly twice the call rate as unrestored sites. This work highlights the benefits of using automated detection techniques that provide quantitative information on species-specific call characteristics and patterns. This type of non-invasive acoustic monitoring provides long-term, semi-continuous information on animal behavior and abundance, and operates effectively in settings that are otherwise difficult to sample.

Published

2017

5. Sources and levels of ambient ocean sound near the Antarctic Peninsula

Author

Robert P. Dziak, Won Sang Lee, Tai-Kwan Lau, Joseph H. Haxel, DelWayne R. Bohnenstiehl, David K. Mellinger, Minkyu Park, Mattew J. Fowler, Haruyoshi Matsumoto, and Kathleen M. Stafford

Subjects

Sound Spectrography, Oceans and Seas, Ambient noise level, Antarctic Regions, lcsh:Medicine, Deep sea, biology.animal, Sea ice, Animals, lcsh:Science, Sound (geography), geography, Multidisciplinary, geography.geographical_feature_category, Fin Whale, biology, Balaenoptera, Hydrophone, Whale, lcsh:R, biology.organism_classification, Iceberg, Sound, Oceanography, lcsh:Q, Vocalization, Animal, Noise, Geology, Research Article

Abstract

Arrays of hydrophones were deployed within the Bransfield Strait and Scotia Sea (Antarctic Peninsula region) from 2005 to 2009 to record ambient ocean sound at frequencies of up to 125 and 500 Hz. Icequakes, which are broadband, short duration signals derived from fracturing of large free-floating icebergs, are a prominent feature of the ocean soundscape. Icequake activity peaks during austral summer and is minimum during winter, likely following freeze-thaw cycles. Iceberg grounding and rapid disintegration also releases significant acoustic energy, equivalent to large-scale geophysical events. Overall ambient sound levels can be as much as ~10-20 dB higher in the open, deep ocean of the Scotia Sea compared to the relatively shallow Bransfield Strait. Noise levels become lowest during the austral winter, as sea-ice cover suppresses wind and wave noise. Ambient noise levels are highest during austral spring and summer, as surface noise, ice cracking and biological activity intensifies. Vocalizations of blue (Balaenoptera musculus) and fin (B. physalus) whales also dominate the long-term spectra records in the 15-28 and 89 Hz bands. Blue whale call energy is a maximum during austral summer-fall in the Drake Passage and Bransfield Strait when ambient noise levels are a maximum and sea-ice cover is a minimum. Fin whale vocalizations were also most common during austral summer-early fall months in both the Bransfield Strait and Scotia Sea. The hydrophone data overall do not show sustained anthropogenic sources (ships and airguns), likely due to low coastal traffic and the typically rough weather and sea conditions of the Southern Ocean.

Published

2015

6. Oyster Larvae Settle in Response to Habitat-Associated Underwater Sounds

Author

Ashlee Lillis, David B. Eggleston, and DelWayne R. Bohnenstiehl

Subjects

0106 biological sciences, Multidisciplinary, Statement (logic), business.industry, Science, 010604 marine biology & hydrobiology, lcsh:R, Correction, Library science, lcsh:Medicine, 01 natural sciences, Medicine, lcsh:Q, 14. Life underwater, Student research, business, lcsh:Science, 010606 plant biology & botany

Abstract

Two funding organizations and grants were incorrectly omitted from the Funding Statement. The Funding Statement should read: "Funding was provided by National Science Foundation Grants OCE-1234688 and DDIG-1210292, PADI Foundation Grant 5145 and a National Shellfisheries Association Melbourne R. Carriker Student Research Grant. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript."

Published

2014

7. Oyster larvae settle in response to habitat-associated underwater sounds

Author

DelWayne R. Bohnenstiehl, Ashlee Lillis, and David B. Eggleston

Subjects

0106 biological sciences, Oyster, lcsh:Medicine, 010603 evolutionary biology, 01 natural sciences, biology.animal, North Carolina, Animals, 14. Life underwater, Crassostrea, lcsh:Science, Reef, Sound (geography), Ecosystem, geography, Multidisciplinary, geography.geographical_feature_category, biology, Behavior, Animal, Settlement (structural), Ecology, 010604 marine biology & hydrobiology, lcsh:R, Estuary, Coral reef, biology.organism_classification, Fishery, Sound, Acoustic Stimulation, Benthic zone, Larva, lcsh:Q, Cues, Eastern oyster, Research Article

Abstract

Following a planktonic dispersal period of days to months, the larvae of benthic marine organisms must locate suitable seafloor habitat in which to settle and metamorphose. For animals that are sessile or sedentary as adults, settlement onto substrates that are adequate for survival and reproduction is particularly critical, yet represents a challenge since patchily distributed settlement sites may be difficult to find along a coast or within an estuary. Recent studies have demonstrated that the underwater soundscape, the distinct sounds that emanate from habitats and contain information about their biological and physical characteristics, may serve as broad-scale environmental cue for marine larvae to find satisfactory settlement sites. Here, we contrast the acoustic characteristics of oyster reef and off-reef soft bottoms, and investigate the effect of habitat-associated estuarine sound on the settlement patterns of an economically and ecologically important reef-building bivalve, the Eastern oyster (Crassostrea virginica). Subtidal oyster reefs in coastal North Carolina, USA show distinct acoustic signatures compared to adjacent off-reef soft bottom habitats, characterized by consistently higher levels of sound in the 1.5–20 kHz range. Manipulative laboratory playback experiments found increased settlement in larval oyster cultures exposed to oyster reef sound compared to unstructured soft bottom sound or no sound treatments. In field experiments, ambient reef sound produced higher levels of oyster settlement in larval cultures than did off-reef sound treatments. The results suggest that oyster larvae have the ability to respond to sounds indicative of optimal settlement sites, and this is the first evidence that habitat-related differences in estuarine sounds influence the settlement of a mollusk. Habitat-specific sound characteristics may represent an important settlement and habitat selection cue for estuarine invertebrates and could play a role in driving settlement and recruitment patterns in marine communities.

Published

2013

8. The Curious Acoustic Behavior of Estuarine Snapping Shrimp: Temporal Patterns of Snapping Shrimp Sound in Sub-Tidal Oyster Reef Habitat

Author

Ashlee Lillis, David B. Eggleston, and DelWayne R. Bohnenstiehl

Subjects

0106 biological sciences, Conservation of Natural Resources, Time Factors, Climate, Wavelet Analysis, lcsh:Medicine, Biology, 010603 evolutionary biology, 01 natural sciences, North Carolina, Water Movements, Animals, 14. Life underwater, lcsh:Science, Sound pressure, Sound (geography), geography, Multidisciplinary, geography.geographical_feature_category, Behavior, Animal, Geography, Coral Reefs, 010604 marine biology & hydrobiology, lcsh:R, Marine reserve, Temperature, Estuary, Acoustics, Coral reef, Ostreidae, Circadian Rhythm, Shrimp, Fishery, Sound, Crepuscular, lcsh:Q, Seasons, Estuaries, Bay, Research Article

Abstract

Ocean soundscapes convey important sensory information to marine life. Like many mid-to-low latitude coastal areas worldwide, the high-frequency (>1.5 kHz) soundscape of oyster reef habitat within the West Bay Marine Reserve (36°N, 76°W) is dominated by the impulsive, short-duration signals generated by snapping shrimp. Between June 2011 and July 2012, a single hydrophone deployed within West Bay was programmed to record 60 or 30 seconds of acoustic data every 15 or 30 minutes. Envelope correlation and amplitude information were then used to count shrimp snaps within these recordings. The observed snap rates vary from 1500-2000 snaps per minute during summer to

Published

2016

9. Hurricane impacts on a coral reef soundscape.

Author

Kayelyn R Simmons, David B Eggleston, and DelWayne R Bohnenstiehl

Subjects

Medicine, Science

Abstract

Soundscape ecology is an emerging field in both terrestrial and aquatic ecosystems, and provides a powerful approach for assessing habitat quality and the ecological response of sound-producing species to natural and anthropogenic perturbations. Little is known of how underwater soundscapes respond during and after severe episodic disturbances, such as hurricanes. This study addresses the impacts of Hurricane Irma on the coral reef soundscape at two spur-and-groove fore-reef sites within the Florida Keys USA, using passive acoustic data collected before and during the storm at Western Dry Rocks (WDR) and before, during and after the storm at Eastern Sambo (ESB). As the storm passed, the cumulative acoustic exposure near the seabed at these sites was comparable to a small vessel operating continuously overhead for 1-2 weeks. Before the storm, sound pressure levels (SPLs) showed a distinct pattern of low frequency diel variation and increased high frequency sound during crepuscular periods. The low frequency band was partitioned in two groups representative of soniferous reef fish, whereas the high frequency band represented snapping shrimp sound production. Daily daytime patterns in low-frequency sound production largely persisted in the weeks following the hurricane. Crepuscular sound production by snapping shrimp was maintained post-hurricane with only a small shift (~1.5dB) in the level of daytime vs nighttime sound production for this high frequency band. This study suggests that on short time scales, temporal patterns in the coral reef soundscape were relatively resilient to acoustic energy exposure during the storm, as well as changes in the benthic habitat and environmental conditions resulting from hurricane damage.

Published

2021

10. Correction: Hurricane impacts on a coral reef soundscape.

Author

Kayelyn R Simmons, David B Eggleston, and DelWayne R Bohnenstiehl

Subjects

Medicine, Science

Abstract

[This corrects the article DOI: 10.1371/journal.pone.0244599.].

Published

2021

11. Oyster toadfish (Opsanus tau) boatwhistle call detection and patterns within a large-scale oyster restoration site.

Author

Shannon W Ricci, DelWayne R Bohnenstiehl, David B Eggleston, M Lisa Kellogg, and R Patrick Lyon

Subjects

Medicine, Science

Abstract

During May 2015, passive acoustic recorders were deployed at eight subtidal oyster reefs within Harris Creek Oyster Sanctuary in Chesapeake Bay, Maryland USA. These sites were selected to represent both restored and unrestored habitats having a range of oyster densities. Throughout the survey, the soundscape within Harris Creek was dominated by the boatwhistle calls of the oyster toadfish, Opsanus tau. A novel, multi-kernel spectral correlation approach was developed to automatically detect these boatwhistle calls using their two lowest harmonic bands. The results provided quantitative information on how call rate and call frequency varied in space and time. Toadfish boatwhistle fundamental frequency ranged from 140 Hz to 260 Hz and was well correlated (r = 0.94) with changes in water temperature, with the fundamental frequency increasing by ~11 Hz for every 1°C increase in temperature. The boatwhistle call rate increased from just a few calls per minute at the start of monitoring on May 7th to ~100 calls/min on May 10th and remained elevated throughout the survey. As male toadfish are known to generate boatwhistles to attract mates, this rapid increase in call rate was interpreted to mark the onset of spring spawning behavior. Call rate was not modulated by water temperature, but showed a consistent diurnal pattern, with a sharp decrease in rate just before sunrise and a peak just after sunset. There was a significant difference in call rate between restored and unrestored reefs, with restored sites having nearly twice the call rate as unrestored sites. This work highlights the benefits of using automated detection techniques that provide quantitative information on species-specific call characteristics and patterns. This type of non-invasive acoustic monitoring provides long-term, semi-continuous information on animal behavior and abundance, and operates effectively in settings that are otherwise difficult to sample.

Published

2017

12. The Curious Acoustic Behavior of Estuarine Snapping Shrimp: Temporal Patterns of Snapping Shrimp Sound in Sub-Tidal Oyster Reef Habitat.

Author

DelWayne R Bohnenstiehl, Ashlee Lillis, and David B Eggleston

Subjects

Medicine, Science

Abstract

Ocean soundscapes convey important sensory information to marine life. Like many mid-to-low latitude coastal areas worldwide, the high-frequency (>1.5 kHz) soundscape of oyster reef habitat within the West Bay Marine Reserve (36°N, 76°W) is dominated by the impulsive, short-duration signals generated by snapping shrimp. Between June 2011 and July 2012, a single hydrophone deployed within West Bay was programmed to record 60 or 30 seconds of acoustic data every 15 or 30 minutes. Envelope correlation and amplitude information were then used to count shrimp snaps within these recordings. The observed snap rates vary from 1500-2000 snaps per minute during summer to

Published

2016

13. Oyster larvae settle in response to habitat-associated underwater sounds.

Author

Ashlee Lillis, David B Eggleston, and DelWayne R Bohnenstiehl

Subjects

Medicine, Science

Abstract

Following a planktonic dispersal period of days to months, the larvae of benthic marine organisms must locate suitable seafloor habitat in which to settle and metamorphose. For animals that are sessile or sedentary as adults, settlement onto substrates that are adequate for survival and reproduction is particularly critical, yet represents a challenge since patchily distributed settlement sites may be difficult to find along a coast or within an estuary. Recent studies have demonstrated that the underwater soundscape, the distinct sounds that emanate from habitats and contain information about their biological and physical characteristics, may serve as broad-scale environmental cue for marine larvae to find satisfactory settlement sites. Here, we contrast the acoustic characteristics of oyster reef and off-reef soft bottoms, and investigate the effect of habitat-associated estuarine sound on the settlement patterns of an economically and ecologically important reef-building bivalve, the Eastern oyster (Crassostrea virginica). Subtidal oyster reefs in coastal North Carolina, USA show distinct acoustic signatures compared to adjacent off-reef soft bottom habitats, characterized by consistently higher levels of sound in the 1.5-20 kHz range. Manipulative laboratory playback experiments found increased settlement in larval oyster cultures exposed to oyster reef sound compared to unstructured soft bottom sound or no sound treatments. In field experiments, ambient reef sound produced higher levels of oyster settlement in larval cultures than did off-reef sound treatments. The results suggest that oyster larvae have the ability to respond to sounds indicative of optimal settlement sites, and this is the first evidence that habitat-related differences in estuarine sounds influence the settlement of a mollusk. Habitat-specific sound characteristics may represent an important settlement and habitat selection cue for estuarine invertebrates and could play a role in driving settlement and recruitment patterns in marine communities.

Published

2013