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Trends in soil characteristics along a recently deglaciated foreland on Anvers Island, Antarctic Peninsula

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Abstract

We assessed patterns in soil development at a recently deglaciated foreland on Anvers Island on the Antarctic Peninsula. Soil samples were collected along transects extending 35 m over bare ground from the edge of a receding glacier; the far end of these transects has been ice free for approximately 20 years. We also compared soils at the far end of these transects under bare ground to those under canopies of isolated individuals of Deschampsia antarctica, a caespitose grass, that had recently colonized the site (established for <6 years). In addition, we compared soils at this young foreland to those in a well-developed tundra island that has been ice free for at least several hundred years. At the foreland site, soil moisture was greatest near the glacier, consistent with proximity to meltwater, and declined with distance from the glacier. This decline in soil moisture may explain the decrease in litter decomposition rates and the greater soil nitrate (NO3 ) concentrations that we observed with distance from the glacier. The greater soil moisture near the glacier likely promoted leaching and transport of NO3 to drier soils away from the glacier. The presence of D. antarctica at the glacier foreland had little effect on soil properties, which is not surprising considering it had only colonized sampling areas during the previous 5 years. Compared to the foreland, which contained only mineral soil, soil at the older tundra site had a 2.5- to 5-cm-thick organic horizon that had much higher concentrations of total carbon, nitrogen, and NO3 .

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References

  • Allen SE, Heal OW (1970) Soils of the maritime Antarctic zone. In: Holdgate MW (ed) Antarctic ecology. Academic Press, London, pp 693–696

    Google Scholar 

  • Allison VJ, Condron LM, Peltzer DA, Richardson SJ, Turner BL (2007) Changes in enzyme activities and soil microbial community composition along carbon and nutrient gradients at the Franz Josef chronosequence, New Zealand. Soil Biol Biochem 39:1770–1781

    Article  CAS  Google Scholar 

  • Bekku Y, Nakatsubo T, Kume A, Koizumi H (2004) Soil microbial biomass, respiration rate, and temperature dependence on a successional glacier foreland in Ny-Alesund, Svalbard. Arct Antarct Alp Res 36:395–399

    Article  Google Scholar 

  • Beyer L, Blume HP, Bölter M, Kappen L, Seppelt RD (2002) Soil ecology in relation to plant patterns. In: Beyer L, Bölter M (eds) Geoecology of Antarctic ice-free coastal landscapes. Ecological studies, vol 154. Springer, Berlin, pp 375–391

    Google Scholar 

  • Blume HP, Kuhn D, Bölter M (2002) Weathering and soil formation. In: Beyer L, Bölter M (eds) Geoecology of Antarctic ice-free coastal landscapes. Ecological studies, vol 154. Springer, Berlin, pp 115–138

    Google Scholar 

  • Bokhorst S, Huiskes A, Convey P, Aerts R (2007) External nutrient inputs into terrestrial ecosystems of the Falkland Islands and the Maritime Antarctic region. Polar Biol 30:1315–1321

    Article  Google Scholar 

  • Bölter M, Kandeler E, Pietr SJ, Seppelt RD (2002) Heterotrophic microbes, microbial and enzymatic activity in Antarctic soils. In: Beyer L, Bölter M (eds) Geoecology of Antarctic ice-free coastal landscapes. Ecological studies, vol 154. Springer, Berlin, pp 189–214

    Google Scholar 

  • Chapin FS, Walker LR, Fastie CL, Sharman LC (1994) Mechanisms of primary succession following deglaciation at Glacier Bay, Alaska. Ecol Monogr 64:149–175

    Article  Google Scholar 

  • Convey P, Smith RIL (2006) Responses of terrestrial Antarctic ecosystems to climate change. Plant Ecol 182:1–10

    Google Scholar 

  • Cook FJ, Orchard VA (2008) Relationships between soil respiration and soil moisture. Soil Biol Biochem 40:1013–1018

    Article  CAS  Google Scholar 

  • Cook AJ, Fox AJ, Vaughan DG, Ferrigno JG (2005) Retreating glacier fronts on the Antarctic Peninsula over the past half-century. Science 308:541–544

    Article  CAS  PubMed  Google Scholar 

  • Cooper WS (1923) The recent ecological history of Glacier Bay, Alaska: the present vegetation cycle. Ecology 4:223–246

    Article  Google Scholar 

  • Cooper WS (1937) The problem of Glacier Bay, Alaska: a study of glacier variations. Geogr Rev 27:37–62

    Article  Google Scholar 

  • Crocker RL, Major J (1955) Soil development in relation to vegetation and surface age at Glacier Bay, Alaska. J Ecol 43:427–448

    Article  Google Scholar 

  • Day TA, Ruhland CT, Grobe CW, Xiong FS (1999) Growth and reproduction of Antarctic vascular plants in response to warming and UV-B radiation reductions in the field. Oecologia 119:24–35

    Article  Google Scholar 

  • Day TA, Ruhland CT, Xiong FS (2008) Warming increases aboveground plant biomass and C stocks in vascular-plant-dominated Antarctic tundra. Global Change Biol 14:1827–1843

    Article  Google Scholar 

  • Day TA, Ruhland CT, Strauss SL, Park J, Krieg ML, Krna MA, Bryant DM (2009) Response of plants and the dominant microarthropod, Cryptopygus antarcticus, to warming and contrasting precipitation regimes in Antarctic tundra. Global Change Biol 15:1640–1651

    Article  Google Scholar 

  • De Vries W, Breeuwsma A (1987) The relation between soil acidification and element cycling. Water Air Soil Pollut 35:293–310

    Article  Google Scholar 

  • Dolezal J, Homma K, Takahashi K, Vyatkina MP, Yakubov V, Vetrova VP, Hara T (2008) Primary succession following deglaciation at Koryto Glacier Valley, Kamchatka. Arct Antarct Alp Res 40:309–322

    Article  Google Scholar 

  • Engelen A, Convey P, Hodgson DA, Worland MR, Ott S (2008) Soil properties of an Antarctic inland site: implications for ecosystem development. Polar Biol 31:1453–1460

    Article  Google Scholar 

  • Fierer N, Allen AS, Schimel JP, Holden PA (2003) Controls on microbial CO2 production: a comparison of surface and subsurface soil horizons. Global Change Biol 9:1322–1332

    Article  Google Scholar 

  • Fogg GE, Stewart WD (1968) In situ determination of biological nitrogen fixation in Antarctica. Br Antarct Surv Bull 15:39–46

    Google Scholar 

  • Fowbert JA, Smith RIL (1994) Rapid population increases in native vascular plants in the Argentine Islands, Antarctic Peninsula. Arct Antarct Alp Res 26:290–296

    Google Scholar 

  • Frenot Y, van Vliet-Lanoe B, Gloaguen JC (1995) Particle translocation and initial soil development on a glacier foreland, Kerguelen Islands, Subantarctic. Arct Antarct Alp Res 27:107–115

    Google Scholar 

  • Giblin AE, Nadelhoffer KJ, Shaver GR, Laundre JA, McKerrow AJ (1991) Biogeochemical diversity along a riverside toposequence in Arctic Alaska. Ecol Monogr 61:415–435

    Article  Google Scholar 

  • Grobe CW, Ruhland CT, Day TA (1997) A new population of Colobanthus quitensis near Arthur Harbor, Antarctica: correlating recruitment with warmer summer temperatures. Arct Antarct Alp Res 29:217–221

    Google Scholar 

  • Hodkinson ID, Coulson SJ, Webb NR (2003) Community assembly along proglacial chronosequences in the high Arctic: vegetation and soil development in northwest Svalbard. J Ecol 91:651–663

    Article  Google Scholar 

  • Hood EW, Williams MW, Caine N (2003) Landscape controls on organic and inorganic nitrogen leaching across an alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range. Ecosystems 6:31–45

    Article  CAS  Google Scholar 

  • Huggett RJ (1998) Soil chronosequences, soil development, and soil evolution: a critical review. Catena 32:155–172

    Article  Google Scholar 

  • IPCC (2007) Climate change 2007—The physical science basis: contribution of the working group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge

    Google Scholar 

  • Jenny H (1941) Factors of soil formation: a system of quantitative pedology. Dover, New York

    Google Scholar 

  • Jenny H (1980) The soil resource: origin and behavior. Springer, New York

    Google Scholar 

  • Jones CC, del Moral R (2005) Patterns of primary succession on the foreland of Coleman Glacier, Washington, USA. Plant Ecol 180:105–116

    Article  Google Scholar 

  • Jumpponen A, Vare H, Mattson KG, Ohtonen R, Trappe JM (1999) Characterization of ‘safe sites’ for pioneers in primary succession on recently deglaciated terrain. J Ecol 87:98–105

    Article  Google Scholar 

  • Lee X, Wu HJ, Sigler J, Oishi C, Siccama T (2004) Rapid and transiet response of soil respiration to rain. Global Change Biol 10:1017–1026

    Article  Google Scholar 

  • Lindeboom HJ (1984) The nitrogen pathway in a penguin rookery. Ecology 65:269–277

    Article  CAS  Google Scholar 

  • Matthews JA (1992) The ecology of recently-deglaciated terrain: a geoecological approach to glacier forelands and primary succession. Cambridge University Press, Cambridge

    Google Scholar 

  • Minitab Inc (2006) Minitab statistical software, release 15 for Windows, State College, PA

  • Murphy EJ, Clark A, Symon C, Priddle J (1995) Temporal variation in Antarctic sea ice—analysis of a long term fast-ice record from the South Orkney Islands. Deep-Sea Res 42:1045–1062

    Article  Google Scholar 

  • Navas A, Lopez-Martínez J, Casa J, Machín J, Durán JJ, Serrano E, Cuchi J-A, Mink S (2008) Soil characteristics on varying lithological substrates in the South Shetland Islands, maritime Antarctica. Geoderma 144:123–139

    Article  CAS  Google Scholar 

  • Orchard VA, Cook FJ (1983) Relationship between soil respiration and soil moisture. Soil Biol Biochem 15:447–453

    Article  Google Scholar 

  • Park J, Day TA, Strauss S, Ruhland CT (2007) Biogeochemical pools and fluxes of carbon and nitrogen in a maritime tundra near penguin colonies along the Antarctic Peninsula. Polar Biol 30:199–207

    Article  Google Scholar 

  • Parnikoza I, Convey P, Dykyy I, Trokhymets V, Milinevsky G, Tyschenko O, Inozemtseva D, Kozeretska I (2009) Current status of the Antarctic herb tundra formation in the Central Argentine Islands. Global Change Biol 15:1685–1693

    Article  Google Scholar 

  • Robertson GPP, Coleman DC, Bledsoe CS, Sollins P (1999) Standard soil methods for long-term ecological research. Oxford University Press, New York

    Google Scholar 

  • Schmidt SK, Reed SC, Nemergut DR, Grandy AS, Cleveland CC, Weintraub MN, Hill AW, Costello EK, Meyer AF, Neff JC, Martin AM (2008) The earliest stages of ecosystem succession in high-elevation (5000 metres above sea level), recently deglaciated soils. Proc R Soc B 275:2793–2802

    Article  CAS  PubMed  Google Scholar 

  • Simas FNB, Schaefer CEGR, Melo VF, Albuquerque-Filho MR, Michel RFM, Pereira VV, Gomes MRM, da Costa LM (2007) Ornithogenic cryosols from Maritime Antarctica: phosphatization as a soil forming process. Geoderma 138:191–203

    Article  CAS  Google Scholar 

  • Smith RIL (1982) Plant succession and re-exposed moss banks on a deglaciated headland in Arthur Harbour, Anvers Island. Br Antarct Surv Bull 51:193–199

    Google Scholar 

  • Smith RIL (1994) Vascular plants as bioindicators of regional warming in Antarctica. Oecologia 99:322–328

    Article  Google Scholar 

  • Smith RIL (2000) Plant colonization on a 45-year sequence of annual micromoraines on a South Georgia glacier foreland. In: Davison W, Howard-Williams C, Broady P (eds) Antarctic ecosystems: models for wider ecological understanding. The Caxton Press, Christchurch, pp 225–232

    Google Scholar 

  • Smith RC, Stammerjohn SE, Baker KS (1996) Surface air temperature variation in the western Antarctic Peninsula region. In: Ross RM, Hofmann EE, Quetin LB (eds) Foundations for ecological research west of the Antarctic Peninsula. Antarctic Research Series, vol 70. American Geophysical Union, Washington, DC, pp 105–121

    Google Scholar 

  • Smith RC, Ainley D, Baker K, Domack E, Emslie S, Fraser B, Kennett J, Leventer A, Mosley Thompson E, Stammerjohn S, Vernet M (1999) Marine ecosystem sensitivity to climate change: historical observations and paleoecological records reveal ecological transitions in the Antarctic Peninsula region. Bioscience 49:393–404

    Article  Google Scholar 

  • Tatur A (2002) Ornithogenic ecosystems in the maritime Antarctic—formation, development and disintegration. In: Beyer L, Bölter M (eds) Geoecology of Antarctic ice-free coastal landscapes. Ecological studies, vol 154. Springer, Berlin, pp 161–184

    Google Scholar 

  • Thompson LG, Peel DA, Mosley-Thompson E (1994) Climate since A.D. 1510 on Dyer Plateau, Antarctic Peninsula: evidence for recent climate change. Ann Glaciol 20:420–426

    CAS  Google Scholar 

  • Tscherko D, Rustemeier J, Richter A, Wanek W, Kandeler E (2003) Functional diversity of the soil microflora in primary succession across two glacier forelands in the Central Alps. Eur J Soil Sci 54:685–696

    Article  Google Scholar 

  • Turner J, Colwell SR, Marshall GJ, Lachlan-Cope TA, Carleton AM, Jones PD, Lagun V, Reid PA, Lagovkina S (2005) Antarctic climate change during the last 50 years. Int J Climatol 25:279–294

    Article  Google Scholar 

  • Vaughan CS, Doake CSM (1996) Recent atmospheric warming and retreat of ice shelves on the Antarctic Peninsula. Nature 379:328–330

    Article  CAS  Google Scholar 

  • Vaughan DG, Marshall GJ, Connolley WM, King JC, Mulvaney R (2001) Climate change—devil in the detail. Science 293:1777–1779

    Article  CAS  PubMed  Google Scholar 

  • Vaughan DG, Marshall GJ, Connolley WM, Parkinson C, Mulvaney RL, Hodgson DA, King JC, Pudsey CJ, Turner J (2003) Recent rapid regional climate warming on the Antarctic Peninsula. Clim Change 60:243–274

    Article  Google Scholar 

  • Vetaas OR (1994) Primary succession of plant assemblages on a glacier foreland—Bodalsbreen, Southern Norway. J Biogeogr 21:297–308

    Article  Google Scholar 

  • Wynn-Williams DD (1982) Simulation of seasonal changes in microbial activity of maritime Antarctic peat. Soil Biol Biochem 14:1–12

    Article  CAS  Google Scholar 

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Acknowledgments

We thank field team member Caroline DeVan and personnel at Palmer Station and Raytheon Polar Services Company for their assistance in field collection, administrative and logistical support. This work was supported by National Science Foundation grant OPP-0230579.

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Authors and Affiliations

  1. School of Life Sciences, Arizona State University, Tempe, AZ, 85287-4601, USA

    Sarah L. Strauss & Thomas A. Day

  2. Department of Biological Sciences, TS-242 Trafton Sciences Center, Minnesota State University, Mankato, MN, 56001, USA

    Christopher T. Ruhland

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  1. Sarah L. Strauss
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Correspondence to Sarah L. Strauss.

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Strauss, S.L., Ruhland, C.T. & Day, T.A. Trends in soil characteristics along a recently deglaciated foreland on Anvers Island, Antarctic Peninsula. Polar Biol 32, 1779–1788 (2009). https://doi.org/10.1007/s00300-009-0677-3

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