Field and microcosm studies of decomposition and soil biota in a cold dessert soil. Ecosystems 5, (2002).
Invertebrate diversity in Taylor Valley soils and sediments. Antarctic Journal of the United States 33, 13-16 (2005).
Lakes and reservoirs as regulators of carbon cycling and climate. Limnology and Oceanography 54 part 2, 2298–2314 (2009).
Life in Antarctic Deserts and other Cold Dry Environments 195-220 (Cambridge University Press, 2010).
The chemical composition of runoff from Canada Glacier, Antarctica: implications for glacier hydrology during a cool summer. Annals of Glaciology 40, 15-19 (2005).
Perturbation of hydrochemical conditions in natural microcosms entombed within Antarctic ice. Ice and Climate News 6, 22-23 (2005).
Extreme hydrochemical conditions in natural microcosms entombed within Antarctic ice. Hydrological Processes 18, 379-387 (2004).
The Life Cycle of the Antarctic Nematode Plectus murrayi Under Laboratory Conditions. Journal of nematology 45, 39-42 (2013).
Microbial dynamics and flagellate grazing during transition to winter in Lakes Hoare and Bonney, Antarctica. FEMS Microbiology Ecology 82, 449 - 458 (2012).
A communal catalogue reveals Earth’s multiscale microbial diversity. Nature 551, (2017).
Provisional checklist of terrestrial heterotrophic protists from Antarctica. Antarctic Science (2019). doi:10.1017/S0954102019000361
Extremophiles (CRC Press, 2018). at <https://www.taylorfrancis.com/books/e/9781498774932/chapters/10.1201%2F9781315154695-9>
Impact of nitrogen and phosphorus on phytoplankton production and bacterial community structure in two stratified Antarctic lakes: a bioassay approach. Polar Biology 40, (2017).
Influence of abiotic drivers (light and nutrients) on photobiology and diversity of Antarctic lake phytoplankton communities. Department of Microbiology Ph.D., (2016).
Spring thaw ionic pulses boost nutrient availability and microbial growth in entombed Antarctic Dry Valley cryoconite holes. Frontiers in Microbiology 5, (2014).
The chemical evolution of Canada Glacier melt: supraglacial and proglacial waters in Taylor Valley, Antarctica. M.S., (2002).
Bacterial growth in Antarctic lakes: The role of phytoplankton extracellular release. Bacterial growth in Antarctic lakes: The role of phytoplankton extracellular (1996).
Responses of bacterial growth to inorganic and organic nutrient enrichment in the lakes of the dry valleys, Antarctica. Antarctic Journal of the US 30, 303-305 (1995).
Factors Affecting the Distribution and Dynamics of Bacterioplankton Biomass and Diversity in Taylor Valley Lakes, Antarctica. Ph.D., (1999).
Life in Antarctic Deserts and other Cold Dry Environments: Astrobiological Analogues 5, 221-257 (Cambridge University Press, 2010).
Bacterioplankton dynamics in the McMurdo Dry Valley lakes, Antarctica: Production and biomass loss over four seasons. Microbial Ecology 36, 239-250 (1998).
Bacterial dissolved organic carbon demand in antarctic dry valley lakes. Limnology and Oceanography 46, 1189-1194 (2001).
The role of phytoplankton extracellular release in bacterioplankton growth of Taylor Valley Lakes, Antarctica. Antarctic Journal of the United States - 1996 Review Issue (NSF 98-28) 31, 211-212 (1998).
Long-term perspectives on biodiversity-ecosystem function. Bioscience 89-98 (2003).
Soil animal responses to moisture availability are largely scale, not ecosystem dependent: insight from a cross-site study. Global Change Biology 20, 2631 - 2643 (2014).