Long‐term patterns in ecosystem phenology near Palmer Station, Antarctica, from the perspective of the Adélie penguin

Megan A. Cimino; John A. Conroy; Elizabeth Connors; Jeff Bowman; Andrew Corso; Hugh Ducklow; William Fraser; Ari Friedlaender; Heather Hyewon Kim; Gregory D. Larsen; Carlos Moffat; Ross Nichols; Logan Pallin; Donna Patterson‐Fraser; Darren Roberts; Megan Roberts; Deborah K. Steinberg; Patricia Thibodeau; Rebecca Trinh; Oscar Schofield; Sharon Stammerjohn

doi:10.1002/ecs2.4417

Ecosphere (Feb 2023)

Long‐term patterns in ecosystem phenology near Palmer Station, Antarctica, from the perspective of the Adélie penguin

Megan A. Cimino,
John A. Conroy,
Elizabeth Connors,
Jeff Bowman,
Andrew Corso,
Hugh Ducklow,
William Fraser,
Ari Friedlaender,
Heather Hyewon Kim,
Gregory D. Larsen,
Carlos Moffat,
Ross Nichols,
Logan Pallin,
Donna Patterson‐Fraser,
Darren Roberts,
Megan Roberts,
Deborah K. Steinberg,
Patricia Thibodeau,
Rebecca Trinh,
Oscar Schofield,
Sharon Stammerjohn

Affiliations

Megan A. Cimino: Institute of Marine Sciences, University of California Santa Cruz Santa Cruz California USA
John A. Conroy: Virginia Institute of Marine Science, William & Mary Gloucester Point Virginia USA
Elizabeth Connors: Scripps Institution of Oceanography UC San Diego La Jolla California USA
Jeff Bowman: Scripps Institution of Oceanography UC San Diego La Jolla California USA
Andrew Corso: Virginia Institute of Marine Science, William & Mary Gloucester Point Virginia USA
Hugh Ducklow: Department of Earth and Environmental Sciences Columbia University New York New York USA
William Fraser: Polar Oceans Research Group Sheridan Montana USA
Ari Friedlaender: Institute of Marine Sciences, University of California Santa Cruz Santa Cruz California USA
Heather Hyewon Kim: Department of Marine Chemistry and Geochemistry Woods Hole Oceanographic Institution Woods Hole Massachusetts USA
Gregory D. Larsen: Nicholas School of the Environment Duke University Marine Laboratory Beaufort North Carolina USA
Carlos Moffat: School of Marine Science & Policy University of Delaware Newark Delaware USA
Ross Nichols: Institute of Marine Sciences, University of California Santa Cruz Santa Cruz California USA
Logan Pallin: Department of Ecology and Evolutionary Biology University of California Santa Cruz, Ocean Health Building Santa Cruz California USA
Donna Patterson‐Fraser: Polar Oceans Research Group Sheridan Montana USA
Darren Roberts: Institute of Marine Sciences, University of California Santa Cruz Santa Cruz California USA
Megan Roberts: Institute of Marine Sciences, University of California Santa Cruz Santa Cruz California USA
Deborah K. Steinberg: Virginia Institute of Marine Science, William & Mary Gloucester Point Virginia USA
Patricia Thibodeau: University of Rhode Island, Graduate School of Oceanography Kingston Rhode Island USA
Rebecca Trinh: Department of Earth and Environmental Sciences Columbia University New York New York USA
Oscar Schofield: Center of Ocean Observing Leadership Rutgers University New Brunswick New Jersey USA
Sharon Stammerjohn: Institute of Arctic and Alpine Research University of Colorado Boulder Colorado USA

DOI: https://doi.org/10.1002/ecs2.4417
Journal volume & issue: Vol. 14, no. 2
pp. n/a – n/a

Abstract

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Abstract Climate change is leading to phenological shifts across a wide range of species globally. Polar oceans are hotspots of rapid climate change where sea ice dynamics structure ecosystems and organismal life cycles are attuned to ice seasonality. To anticipate climate change impacts on populations and ecosystem services, it is critical to understand ecosystem phenology to determine species activity patterns, optimal environmental windows for processes like reproduction, and the ramifications of ecological mismatches. Since 1991, the Palmer Antarctica Long‐Term Ecological Research (LTER) program has monitored seasonal dynamics near Palmer Station. Here, we review the species that occupy this region as year‐round residents, seasonal breeders, or periodic visitors. We show that sea ice retreat and increasing photoperiod in the spring trigger a sequence of events from mid‐November to mid‐February, including Adélie penguin clutch initiation, snow melt, calm conditions (low winds and warm air/sea temperature), phytoplankton blooms, shallow mixed layer depths, particulate organic carbon flux, peak humpback whale abundances, nutrient drawdown, and bacterial accumulation. Subsequently, from May to June, snow accumulates, zooplankton indicator species appear, and sea ice advances. The standard deviation in the timing of most events ranged from ~20 to 45 days, which was striking compared with Adélie penguin clutch initiation that varied 30 days) than mean dates and the variability in timing was low (<20%) compared with early ice retreat years. Statistical models showed the timing of some events were informative predictors (but not sole drivers) of other events. From an Adélie penguin perspective, earlier sea ice retreat and shifts in the timing of suitable conditions or prey characteristics could lead to mismatches, or asynchronies, that ultimately influence chick survival via their mass at fledging. However, more work is needed to understand how phenological shifts affect chick thermoregulatory costs and the abundance, availability, and energy content of key prey species, which support chick growth and survival. While we did not detect many long‐term phenological trends, we expect that when sea ice trends become significant within our LTER time series, phenological trends and negative effects from ecological mismatches will follow.

Published in Ecosphere

ISSN: 2150-8925 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Biology (General): Ecology
Website: http://esajournals.onlinelibrary.wiley.com/hub/journal/10.1002/(ISSN)2150-8925/

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