McMurdo LTER Publications
The influence of soil biodiversity on hydrological pathways and the transfer of materials between terrestrial and aquatic ecosystems. Ecosystems. 2001;4(421-429).
Organic carbon cycling in Taylor Valley, Antarctica: Quantifying soil reservoirs and soil respiration. Global Change Biology. 2001;7:113-125.
. Soil Biodiversity. In: Global Biodiversity in a Changing Environment. Global Biodiversity in a Changing Environment. New York: Springer Verlag; 2001:47-82.
. Antarctic climate cooling and terrestrial ecosystem response. Nature. 2002;415(6871):517-520. doi:10.1038/nature710.
Distribution and life cycle of Scottnema lindsayae (Nematoda) in Antarctic soils: A modeling analysis of tempaerature responses. Polar Biology. 2002;25:118-125.
. Field and microcosm studies of decomposition and soil biota in a cold dessert soil. Ecosystems. 2002;5(159-170).
. Invertebrates in ornithogenic soils at Ross Island, Antarctica. Polar Biology. 2002;25:569-574.
. Modeling the effects of loss of soil biodiversity on ecosystem function. Global Change Biology. 2002;8:32-49.
. Population age structure of nematodes in the Antarctic Dry Valleys: perspectives on time, space, and habitat suitability. Arctic,Antarctic, and Alpine Research. 2002;34:159-168.
. Recent Temperature Trends in the Antarctic. Nature. 2002;418:291-292.
Snow patch influence on soil biogeochemical processes and invertebrate distribution in the McMurdo Dry Valleys, Antarctica. Arctic, Antarctic, and Alpine Research. 2002;35(1):91-99. doi:10.1657/1523-0430(2003)035[0091:SPIOSB]2.0.CO;2.
Trends in resin and KCl-extractable soil nitrogen across landscape gradients in Taylor Valley, Antarctica. Ecosystems. 2002;5:289-299.
. Long-term perspectives on biodiversity-ecosystem function. Bioscience. 2003;(53):89-98.
Organic matter and soil biota of upland wetlands in Taylor Valley, Antarctica. Polar Biology. 2003;26:1009-1019.
. The Biodiversity and Biogeochemistry of Cryoconite Holes from McMurdo Dry Valley Glaciers, Antarctica. Arctic, Antarctic, and Alpine Research. 2004;36(1):84-91.
. Detritus, trophic dynamics and biodiversity. Ecology Letters. 2004;7:584-600. doi:LTER.
Ecological linkages between aboveground and belowground biota. Science. 2004;304:1629-1633. doi:LTER.
. The need for understanding how biodiversity and ecosystem functioning affect ecosystem services in soil and sediments. In: Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Island Press; 2004.
. The need for understanding how biodiversity and ecosystem functioning affect ecosystem services in soil and sediments. In: Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Island Press; 2004.
. Soil carbon dioxide flux from Antarctic Dry Valley soils. Ecosystems. 2004;7(3):286-295.
. Sustaining Biodiversity and Ecosystem Services in Soil and Sediments. ( ).; 2004. doi:LTER.
. Sustaining Biodiversity and Ecosystem Services in Soil and Sediments. ( ).; 2004. doi:LTER.
. Trophic interactions in a changing world: modelling aboveground-belowground interactions. Basic and Applied Ecology. 2004;5:515-528. doi:LTER.
Understanding the functions of biodiversity in soils and sediments will enhance global ecosystem sustainability and societal well-being. In: Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Island Press; 2004:249-254.
. Understanding the functions of biodiversity in soils and sediments will enhance global ecosystem sustainability and societal well-being. In: Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Sustaining Biodiversity and Ecosystem Services in Soils Sediments. Island Press; 2004:249-254.
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