Your search keyword '"Matthew S. Savoca"' showing total 7 results

1. Marine top predators as climate and ecosystem sentinels

Author

Steven J. Bograd, Kylie L. Scales, Stephanie Brodie, Michael G. Jacox, Gemma Carroll, William J. Sydeman, Elliott L. Hazen, Briana Abrahms, and Matthew S. Savoca

Subjects

Ecology, Environmental science, Ecosystem, Ecology, Evolution, Behavior and Systematics, Apex predator

Published

2019

2. Modelling short‐term energetic costs of sonar disturbance to cetaceans using high‐resolution foraging data

Author

Paolo S. Segre, Jeremy A. Goldbogen, Danuta M. Wisniewska, Max F. Czapanskiy, David E. Cade, William T. Gough, and Matthew S. Savoca

Subjects

disturbance, energetics, Disturbance (geology), Ecology, Foraging, Energetics, anthropogenic noise, High resolution, sublethal effects, sonar, Sonar, Predation, Term (time), cetaceans, Oceanography, predator–prey, Environmental science, foraging behaviour

Abstract

Anthropogenic noise is a pervasive and increasing source of disturbance to wildlife. Marine mammals exhibit behavioural and physiological responses to naval sonar and other sound sources. The lost foraging opportunities and elevated locomotor effort associated with sonar disturbance likely carry energetic costs, which may lead to population-level consequences.We modelled the energetic costs associated with behavioural responses using (a) empirical datasets of cetacean feeding rates and prey characteristics and (b) allometry of swimming performance and metabolic rates.We applied our model to compare the short-term (i.e. the scale of the disturbance response; hours to days) energetic costs of a variety of observed behavioural responses. Efficient foragers (e.g. baleen whales) incur a greater relative energetic cost for mild behavioural responses as compared to the most extreme observed response for larger odontocetes (e.g. beaked whales). Energetic costs are more sensitive to lost feeding opportunities than increased energy expenditure from elevated locomotor effort.To scale up from short-term costs to long-term effects (months to years), future research should address individuals’ capacity to compensate for energetic losses as well as energetic thresholds for demographic rates (survival, fecundity). We discuss how relative energetic costs correlate with species’ pace of life and the implications for conservation planning.Synthesis and applications. Current approaches towards understanding the Population Consequences of Disturbance (PCoD) often must rely on expert opinion due to data deficiency. Our model provides an empirical method for linking behaviour to energetics, which is critical for managers to make informed decisions on actions that may affect marine mammal species. Furthermore, our model is applicable to other forms of disturbance, such as vessel traffic or seismic exploration, and our scaling approach enables risk projections for understudied species.

Published

2021

3. Scaling of oscillatory kinematics and Froude efficiency in baleen whales

Author

Matthew S. Savoca, David E. Cade, Caroline R. Weir, Frank E. Fish, K. C. Bierlich, Jacopo Di Clemente, Andrew Stanworth, William T. Gough, Jeremy A. Goldbogen, Paolo S. Segre, Jean Potvin, Max F. Czapanskiy, John Kennedy, and Hayden J. Smith

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Antarctic Regions, Efficiency, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, Comparative Biomechanics of Movement, Baleen whale, Humpback whale, 03 medical and health sciences, biology.animal, Animals, Minke whale, Thrust, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Swimming, Balaenoptera musculus, Balaenoptera, biology, Fin Whale, Whale, Cetacean, biology.organism_classification, Biomechanical Phenomena, Baleen, 030104 developmental biology, Oceanography, Insect Science, Balaenoptera bonaerensis, Hydrodynamics, Environmental science, Animal Science and Zoology, Research Article

Abstract

High efficiency lunate-tail swimming with high-aspect-ratio lifting surfaces has evolved in many vertebrate lineages, from fish to cetaceans. Baleen whales (Mysticeti) are the largest swimming animals that exhibit this locomotor strategy, and present an ideal study system to examine how morphology and the kinematics of swimming scale to the largest body sizes. We used data from whale-borne inertial sensors coupled with morphometric measurements from aerial drones to calculate the hydrodynamic performance of oscillatory swimming in six baleen whale species ranging in body length from 5 to 25 m (fin whale, Balaenoptera physalus; Bryde's whale, Balaenoptera edeni; sei whale, Balaenoptera borealis; Antarctic minke whale, Balaenoptera bonaerensis; humpback whale, Megaptera novaeangliae; and blue whale, Balaenoptera musculus). We found that mass-specific thrust increased with both swimming speed and body size. Froude efficiency, defined as the ratio of useful power output to the rate of energy input ( Sloop, 1978), generally increased with swimming speed but decreased on average with increasing body size. This finding is contrary to previous results in smaller animals, where Froude efficiency increased with body size. Although our empirically parameterized estimates for swimming baleen whale drag were higher than those of a simple gliding model, oscillatory locomotion at this scale exhibits generally high Froude efficiency as in other adept swimmers. Our results quantify the fine-scale kinematics and estimate the hydrodynamics of routine and energetically expensive swimming modes at the largest scale., Summary: Tags attached to baleen whales demonstrate how thrust power output, drag coefficient and Froude efficiency scale with swimming speed and body length.

Published

2021

4. Microplastics and microfibers in surface waters of Monterey Bay National Marine Sanctuary, California

Author

Marissa DeVogelaere, Lauren M. Kashiwabara, Jeremy A. Goldbogen, Matthew S. Savoca, Chad King, and Shirel R. Kahane-Rapport

Subjects

0106 biological sciences, Pollution, Microplastics, Mesopelagic zone, media_common.quotation_subject, Seamount, 010501 environmental sciences, Aquatic Science, Oceanography, 01 natural sciences, California, Manta trawl, Marine debris, 0105 earth and related environmental sciences, media_common, Shore, geography, geography.geographical_feature_category, 010604 marine biology & hydrobiology, Bays, Environmental science, Bay, Plastics, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Despite a recent report of high concentrations of microplastics and microfibers in the mesopelagic waters of Monterey Bay National Marine Sanctuary (MBNMS), little is known about these particles in surface waters. From 2017 to 2019, we sampled two nearshore and two offshore locations within MBNMS using a manta trawl and analyzed these samples for microplastics and microfibers. We found an average concentration of 1.32 ± 0.70 (SE) particles per m3. We found the highest concentration of particles closest to shore, and the lowest concentration above the remote Davidson Seamount. Fiber-like debris was more common in offshore, as compared to nearshore, sites. Overall, particles in our samples were primarily buoyant synthetic polymers, including polypropylene and polyethylene. Our results provide baseline data on the degree of microplastic and microfiber pollution in MBNMS surface waters and confirm that this pollution can be found in waters from the surface to at least 1000 m depth.

Published

2020

5. Baleen whale prey consumption based on high-resolution foraging measurements

Author

Gwenith S. Penry, William T. Gough, David Johnston, James A. Fahlbusch, Nicholas D. Pyenson, Max F. Czapanskiy, Jacopo Di Clemente, John Calambokidis, Matthew S. Savoca, Douglas P. Nowacek, Shirel R. Kahane-Rapport, Elliott L. Hazen, Ari S. Friedlaender, David N. Wiley, Paolo S. Segre, Jeremy A. Goldbogen, and K. C. Bierlich

Subjects

Biomass (ecology), Multidisciplinary, Krill, Food Chain, Pacific Ocean, biology, Whale, Euphausia, Iron, Whales, Antarctic Regions, biology.organism_classification, Predation, Baleen whale, Fishery, Baleen, Eating, biology.animal, Predatory Behavior, Environmental science, Animals, Whaling, Biomass, Atlantic Ocean, Euphausiacea

Abstract

Baleen whales influence their ecosystems through immense prey consumption and nutrient recycling1–3. It is difficult to accurately gauge the magnitude of their current or historic ecosystem role without measuring feeding rates and prey consumed. To date, prey consumption of the largest species has been estimated using metabolic models3–9 based on extrapolations that lack empirical validation. Here, we used tags deployed on seven baleen whale (Mysticeti) species (n = 321 tag deployments) in conjunction with acoustic measurements of prey density to calculate prey consumption at daily to annual scales from the Atlantic, Pacific, and Southern Oceans. Our results suggest that previous studies3–9 have underestimated baleen whale prey consumption by threefold or more in some ecosystems. In the Southern Ocean alone, we calculate that pre-whaling populations of mysticetes annually consumed 430 million tonnes of Antarctic krill (Euphausia superba), twice the current estimated total biomass of E. superba10, and more than twice the global catch of marine fisheries today11. Larger whale populations may have supported higher productivity in large marine regions through enhanced nutrient recycling: our findings suggest mysticetes recycled 1.2 × 104 tonnes iron yr−1 in the Southern Ocean before whaling compared to 1.2 × 103 tonnes iron yr−1 recycled by whales today. The recovery of baleen whales and their nutrient recycling services2,3,7 could augment productivity and restore ecosystem function lost during 20th century whaling12,13. A combination of 3D whale locations and acoustic measurements of prey density is used here to show that whales’ consumption of krill is several times larger than often thought.

Published

2020

6. Chemoattraction to dimethyl sulfide links the sulfur, iron, and carbon cycles in high-latitude oceans

Author

Matthew S. Savoca

Subjects

0106 biological sciences, Carbon dioxide in Earth's atmosphere, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, fungi, Iron fertilization, Sulfur cycle, Biogeochemistry, Carbon sequestration, 01 natural sciences, Carbon cycle, Environmental chemistry, Environmental Chemistry, Environmental science, Ecosystem, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

Large marine regions, including the exceptionally productive Southern Ocean, are iron-limited. As a result, there has been substantial interest in iron-fertilizing high nutrient low chlorophyll (HNLC) areas in an effort to sequester atmospheric carbon dioxide. More recently, research has shifted to quantifying the beneficial effects of iron recycling by marine biota. Marine top predators such as whales and seabirds have been examined specifically in this regard as they have high biomass, form dense aggregations, and excrete bioavailable iron in concentrations seven orders of magnitude higher than ambient seawater. Despite it being well established that marine fauna link the iron and carbon cycles, the connection of this process to the sulfur cycle has rarely been considered. The chemoattraction of specific marine fauna to algal-derived dimethyl sulfide (DMS) is key in triggering dense, multi-species foraging aggregations that induce iron recycling, augmenting carbon assimilation. The goal of this paper is twofold; first, to highlight DMS chemoattraction as a behavior that catalyzes carbon sequestration via natural iron fertilization, and second, to identify knowledge gaps that recent biogeochemical advances can address. Fostering this interdisciplinary research will enhance our understanding of global climate regulation, ecosystem services provided by marine top predators, and the biogeochemical cycles of carbon, iron, and sulfur in HNLC waters.

Published

2018

7. Quantifying marine debris associated with coastal golf courses

Author

Michael W. Weber, Alex K. Weber, and Matthew S. Savoca

Subjects

0106 biological sciences, Waste Products, 010604 marine biology & hydrobiology, Water Pollution, Intertidal zone, 010501 environmental sciences, Aquatic Science, Oceanography, 01 natural sciences, Pollution, Debris, California, Point source pollution, Marine debris, Environmental science, Golf, Plastic pollution, Pebble, Bay, Plastics, 0105 earth and related environmental sciences, Environmental Monitoring

Abstract

Identifying terrestrial sources of debris is essential to suppress the flow of plastic to the ocean. Here, we report a novel source of debris to the marine environment. From May 2016 to June 2018, we collected golf balls from coastal environments associated with five courses in Carmel, California. Our 75 collections recovered 39,602 balls from intertidal and nearshore environments adjacent to, or downriver from, the golf courses. Combining our collections with concurrent efforts of the Monterey Bay National Marine Sanctuary and the Pebble Beach Corporation, we report the retrieval of 50,681 balls, totaling approximately 2.5 tons of debris. We also examined decomposition patterns in the collected balls, which illustrate that degradation and loss of microplastic from golf balls to the marine environment may be of concern. Our findings will help to develop and direct mitigation procedures for this region and others with coastal golf courses.

Published

2018