Your search keyword '"Jones, Timothy T."' showing total 6 results

1. How we count counts: Examining influences on detection during shoreline surveys of marine debris

Author

Burgess, Hillary K., Jones, Timothy T., Lindsey, Jacqueline K., Herring, Carlie E., Lippiatt, Sherry M., Parrish, Julia K., and Uhrin, Amy V.

Published

2024

2. Extreme mortality and reproductive failure of common murres resulting from the northeast Pacific marine heatwave of 2014-2016.

Author

Piatt, John F., Parrish, Julia K., Renner, Heather M., Schoen, Sarah K., Jones, Timothy T., Arimitsu, Mayumi L., Kuletz, Kathy J., Bodenstein, Barbara, García-Reyes, Marisol, Duerr, Rebecca S., Corcoran, Robin M., Kaler, Robb S. A., McChesney, Gerard J., Golightly, Richard T., Coletti, Heather A., Suryan, Robert M., Burgess, Hillary K., Lindsey, Jackie, Lindquist, Kirsten, and Warzybok, Peter M.

Subjects

HEAT waves (Meteorology), FORAGE fishes, MORTALITY, SEAWATER, STANDARD deviations, GROUNDFISHES, CALANOIDA, SEA birds

Abstract

About 62,000 dead or dying common murres (Uria aalge), the trophically dominant fish-eating seabird of the North Pacific, washed ashore between summer 2015 and spring 2016 on beaches from California to Alaska. Most birds were severely emaciated and, so far, no evidence for anything other than starvation was found to explain this mass mortality. Three-quarters of murres were found in the Gulf of Alaska and the remainder along the West Coast. Studies show that only a fraction of birds that die at sea typically wash ashore, and we estimate that total mortality approached 1 million birds. About two-thirds of murres killed were adults, a substantial blow to breeding populations. Additionally, 22 complete reproductive failures were observed at multiple colonies region-wide during (2015) and after (2016–2017) the mass mortality event. Die-offs and breeding failures occur sporadically in murres, but the magnitude, duration and spatial extent of this die-off, associated with multi-colony and multi-year reproductive failures, is unprecedented and astonishing. These events co-occurred with the most powerful marine heatwave on record that persisted through 2014–2016 and created an enormous volume of ocean water (the "Blob") from California to Alaska with temperatures that exceeded average by 2–3 standard deviations. Other studies indicate that this prolonged heatwave reduced phytoplankton biomass and restructured zooplankton communities in favor of lower-calorie species, while it simultaneously increased metabolically driven food demands of ectothermic forage fish. In response, forage fish quality and quantity diminished. Similarly, large ectothermic groundfish were thought to have increased their demand for forage fish, resulting in greater top-predator demands for diminished forage fish resources. We hypothesize that these bottom-up and top-down forces created an "ectothermic vise" on forage species leading to their system-wide scarcity and resulting in mass mortality of murres and many other fish, bird and mammal species in the region during 2014–2017. [ABSTRACT FROM AUTHOR]

Published

2020

3. Evaluating Native American Bird Use and Bird Assemblage Variability along the Oregon Coast.

Author

Bovy, Kristine M., Moss, Madonna L., Watson, Jessica E., J. White, Frances, Jones, Timothy T., Ulrich, Heather A., and Parrish, Julia K.

Subjects

NATIVE Americans, BIRD diversity, ANTIQUITIES, BIRDS, COASTS, FOREST birds, WHALES

Abstract

Native American use of birds on the Oregon coast is not well known and has never been synthesized to present a regional understanding. We rectify this by analyzing data from 26 zooarchaeological assemblages, including three previously unpublished bird assemblages: Umpqua/Eden (35DO83), Whale Cove (35LNC60), and the Dunes Site (35CLT27). We employ a series of non-parametric randomization tests to directly evaluate patterns of taxonomic diversity, correlations with nearby breeding colonies, and broader procurement strategies discussed in ethnohistorical accounts. We compare the assemblages to contemporary surveys of naturally beached birds as observed by COASST (Coastal Observation Seabird Survey Team) and evaluate whether archaeological specimens were scavenged from the beach. While 71% of the identified bird remains belong to just three families (Anatidae, Alcidae, and Procellariidae), closer analysis reveals the incredible diversity of birds used by Oregon coast Native Americans. The assemblages vary considerably in terms of taxonomic diversity and composition, leading us to conclude that people used birds opportunistically, likely incorporating multiple strategies, including hunting, collecting beached carcasses and targeting cormorant colonies. We hope that the methods and approaches employed here will inspire other archaeologists to devote more attention to bird assemblages, and how their study can inform conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2019

4. Scale‐dependent spatial patterns in benthic communities around a tropical island seascape.

Author

Aston, Eoghan A., Williams, Gareth J., Green, J. A. Mattias, Davies, Andrew J., Wedding, Lisa M., Gove, Jamison M., Jouffray, Jean‐Baptiste, Jones, Timothy T., and Clark, Jeanette

Subjects

BENTHIC ecology, BIOTIC communities, LANDSCAPE ecology, PREDICTION models, CORAL reef ecology

Abstract

Understanding and predicting patterns of spatial organization across ecological communities is central to the field of landscape ecology, and a similar line of inquiry has begun to evolve sub‐tidally among seascape ecologists. Much of our current understanding of the processes driving marine community patterns, particularly in the tropics, has come from small‐scale, spatially‐discrete data that are often not representative of the broader seascape. Here we expand the spatial extent of seascape ecology studies and combine spatially‐expansive in situ digital imagery, oceanographic measurements, spatial statistics, and predictive modeling to test whether predictable patterns emerge between coral reef benthic competitors across scales in response to intra‐island gradients in physical drivers. We do this around the entire circumference of a remote, uninhabited island in the central Pacific (Jarvis Island) that lacks the confounding effects of direct human impacts. We show, for the first time, that competing benthic groups demonstrate predictable scaling patterns of organization, with positive autocorrelation in the cover of each group at scales < ~1 km. Moreover, we show how gradients in subsurface temperature and surface wave power drive spatially‐abrupt transition points in group dominance, explaining 48–84% of the overall variation in benthic cover around the island. Along the western coast, we documented ten times more sub‐surface cooling‐hours than any other part of the coastline, with events typically resulting in a drop of 1–4°C over a period of < 5 h. These high frequency temperature fluctuations are indicative of upwelling induced by internal waves and here result in localized nitrogen enrichment (NO2 + NO3) that promotes hard coral dominance around 44% of the island's perimeter. Our findings show that, in the absence of confounding direct human impacts, the spatial organization of coral reef benthic competitors are predictable and somewhat bounded across the seascape by concurrent gradients in physical drivers. [ABSTRACT FROM AUTHOR]

Published

2019

5. Designer interfaces: diffusional protection of electrodes using chemical architectures.

Author

Wildgoose, Gregory G., Chevallier, François G., Lei Xiao, Thorogood, Charles A., Wilkins, Shelley J., Crossley, Alison, Li Jiang, Jones, Timothy T. G., Jones, John H., and Compton, Richard G.

Published

2006

6. Lobsters as keystone: Only in unfished ecosystems?

Author

Eddy, Tyler D., Pitcher, Tony J., MacDiarmid, Alison B., Byfield, Tamsen T., Tam, Jamie C., Jones, Timothy T., Bell, James J., and Gardner, Jonathan P.A.

Subjects

*LOBSTER fisheries, *LOBSTERS, *MARINE biology, *ECOLOGICAL models, *MARINE ecological models, *MATHEMATICAL models

Abstract

Highlights: [•] We have developed a present day ecosystem model for the Taputeranga MR. [•] We have historically reconstructed the ecosystem state prior to commercial fishing. [•] We have run future simulations to predict ecosystem response to marine protection. [•] The keystone role of lobster has changed since historical times due to fishing. [•] The Taputeranga MR is predicted to return the ecosystem to a more historical state. [Copyright &y& Elsevier]

Published

2014