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Penguin activity influences soil biogeochemistry and soil respiration in rookeries on Ross Island, Antarctica

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Abstract

Ross Island, Antarctica, is home to the southernmost breeding colonies of Adélie penguins, with associated ornithogenic nutrient enrichment to soil. Most of our knowledge about ornithogenic soils in Antarctica comes from studies of the Peninsula region, with much less known about soils in the Ross Sea region of continental Antarctica where climate is more extreme and biological communities are less diverse. We measured soil properties (pH, salinity, total and organic C and N, extractable mineral N and P), microbial biomass, and CO2 flux at three penguin rookeries on Ross Island differing in colony size and along gradients of penguin activity extending from the colony to soils lacking visible penguin influence. We determined both in situ and potential rates of CO2 flux, as well as the nutrient limitations on C cycling by fertilizing soils with N and P, in controlled laboratory incubations. Larger pools of soil C, N, and P along with elevated soil CO2 flux were found in soils with high penguin activity as compared to areas of low or no apparent activity. In laboratory incubations, CO2 flux was stimulated by addition of C with N or P, but not with N or P alone, suggesting that even with the deposition of large amounts of penguin guano, soil biota are not released from C limitation. The influence of penguin activity was not directly related to colony size but rather to the intensity of activity within the rookery (e.g., frequency of penguin presence). Our results show that penguin-influenced soils are biogeochemical hot spots where altered nutrient pools are associated with increased CO2 flux.

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Acknowledgments

This research was supported by NSF Division of Environmental Biology and Office of Polar Programs grants to the McMurdo LTER program (ANT-0423595), as well as research awards from the Western Alliance for the Expansion of Student Opportunities (WAESO) at ASU. We thank Julia Bradley-Cook, Jennifer Bailard, and Adrien Dahood for their assistance in the field, and Susan Matthews, Jessica Alvarez Guevara, Jacob Ramsey, and Miriam LeBron for their assistance in the laboratory. Logistic support was provided by Raytheon Polar Services and Petroleum Helicopters, Inc., Paul Zietz at Dartmouth, and Cathy Kochert and Sara Ryan at the Goldwater Environmental Lab (ASU) provided analytical services.

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Authors and Affiliations

  1. School of Mathematical and Natural Sciences, Arizona State University at the West Campus, 1407 W. Thunderbird Rd., Glendale, AZ, 85306, USA

    Becky A. Ball & Chelsey R. Tellez

  2. Environmental Studies Program, Dartmouth College, Hanover, NH, 03755, USA

    Ross A. Virginia

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  1. Becky A. Ball
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  2. Chelsey R. Tellez
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Correspondence to Becky A. Ball.

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Ball, B.A., Tellez, C.R. & Virginia, R.A. Penguin activity influences soil biogeochemistry and soil respiration in rookeries on Ross Island, Antarctica. Polar Biol 38, 1357–1368 (2015). https://doi.org/10.1007/s00300-015-1699-7

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  • DOI: https://doi.org/10.1007/s00300-015-1699-7

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