Ben Wilson scite author profile

We conducted a mark‐recapture survey of bottlenose dolphins Tursiops truncatus in the bays, sounds, and estuaries of North Carolina during July 2000, using photographic identification techniques. During this survey we took 7,682 photographs of dolphins and, of these, 3,457 images were of sufficient quality for analysis. We identified 306 dolphins from distinctive nicks and notches on their dorsal fins. Eighry‐six dolphins were photographed on more than one occasion during the course of the survey; one dolphin was photographed on four separate days. We then applied the results of our photographic analyses to several mark‐recapture models and examined potential violations of the assumptions of these models, including an unexpected correlation between photo quality and mark distinctiveness. Our analysis suggests that our results are robusr to possible violations of these assumptions. The resulting estimates were then scaled to account for the proportion (0.46) of unmarked dolphins in the population. Our best estimate of the number of dolphins present in the inshore waters of North Carolina during July 2000 is 1,033 with a 95% Confidence Interval of 860–1,266 (CV = 0.099). Most dolphins were found in the northern part of the study area, which includes the second largest estuarine system in the United States.

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Confusion Reigns? A Review of Marine Megafauna Interactions with Tidal-Stream Environments

Benjamins

Dale²,

Hastie

et al. 2015

119

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Estimating Size and Assessing Trends in a Coastal Bottlenose Dolphin Population

Wilson¹,

Hammond²,

Thompson³

1999

Ecological Applications

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We used a case study of a coastal bottlenose dolphin population to present a framework for determining the number of individuals present and assessing the likely time scale over which trends in abundance may be determined. Such a framework is appropriate for animal species that possess natural markings sufficient for individual recognition, and may be valuable in the development and implementation of management and monitoring programs for vulnerable populations.Population abundance was estimated using mark-recapture methods applied to photoidentification data. This experiment was designed to minimize violation of method assumptions so as to allow use of the most parsimonious model for analysis. The data were examined critically to investigate mark-recapture assumptions, while analytical methods and data were selected to minimize and, where necessary, account for violations. The estimated number of animals with long-lasting marks from left and right side estimates were 73 Ϯ 12 and 80 Ϯ 11 individuals, respectively (means Ϯ 1 SE). When divided by the estimated proportion of such animals in the population (0.57 Ϯ 0.043 and 0.61 Ϯ 0.035, respectively) and averaged, weighted by inverse variance, a total population size of 129 Ϯ 15 individual animals was estimated (95% CI ϭ 110-174 animals).Data on calves observed and carcasses recovered suggest that the population could be increasing or decreasing at an annual rate of up to 5%. A power analysis, undertaken to investigate the length of monitoring program required to detect changes in population abundance at a 90% level of certainty, showed that detection of a trend could only occur following Ͼ8 yr of research effort. Biennial sampling has power similar to that of annual sampling, but savings in resources are offset by the loss of data on the reproductive histories of individuals.

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Bottlenose Dolphins Increase Breathing Synchrony in Response to Boat Traffic

Hastie¹,

Wilson²,

Tufft³

et al. 2003

Marine Mammal Science

107

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To minimize potential impacts of boat traffic on the behavior of cetaceans it is important to assess short‐term behavioral responses to boats and interpret the long‐term consequences of these. Anecdotal descriptions of synchronous behavior in cetaceans are particularly frequent with reports of individuals within schools surfacing to breathe in a coordinated fashion being common. However, quantitative descriptions are rare. This study begins by quantifying synchronous breathing patterns of bottlenose dolphins off northern Scotland. We investigate possible functions of synchrony such as feeding patterns and presence of calves. We then test whether the presence of boat traffic in an area used intensively by dolphins affects their breathing synchrony. Although the majority of dolphin schools observed showed random breathing patterns, 30.5 % of schools showed synchronous breathing. There was no variation in this behavior with respect to identifiable feeding activities. However, synchrony was significantly negatively telated to the presence of calves in the school (χ2= 7.17, df = 1, P = 0.007) and significantly positively related to the presence of boat traffic in the study area (χ= 13.85, df = 1, P = 0.0002). Such consistent short‐term behavioral responses by dolphins may potentially accumulate to produce longer‐term consequences both for individuals and the whole population.

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Ben Wilson

Factors controlling suspended sediment on inner-shelf coral reefs, Townsville, Australia

Abundance of Bottlenose Dolphins in the Bays, Sounds, and Estuaries of North Carolina

Confusion Reigns? A Review of Marine Megafauna Interactions with Tidal-Stream Environments

Estimating Size and Assessing Trends in a Coastal Bottlenose Dolphin Population

Bottlenose Dolphins Increase Breathing Synchrony in Response to Boat Traffic

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