
SPRUCE
Spruce and Peatland Responses
Under Changing Environments
Publications
A comment on Appropriate experimental ecosystem warming methods by ecosystem, objective, and practicality by Aronson and McNulty. AGRICULTURAL AND FOREST METEOROLOGY. 150:497-498.
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2010. Air Flow and Heat Transfer in a Temperature Controlled Open Top Enclosure. ASME International Mechanical Engineering Congress and Exposition.
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2012. High-throughput fluorometric measurement of potential soil extracellular enzyme activities. Journal of Visualized Experiments. 81(e50961)
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2013. Melanin mitigates the accelerated decay of mycorrhizal necromass with peatland warming. Ecology Letters. 22(3):498-505.
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2019. Seasonal patterns of nonstructural carbohydrate reserves in four woody boreal species. The Journal of the Torrey Botanical Society. 145(4):332-339.
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2018. Deep peat warming increases surface methane and carbon dioxide emissions in a black spruce-dominated ombrotrophic bog. Global Change Biology. 23(12):5398-5411.
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2017. Characterizing Peatland Microtopography Using Gradient and Microform-Based ApproachesAbstract. Ecosystems. 23(7):1464-1480.
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2020. Dynamic Vertical Profiles of Peat Porewater Chemistry in a Northern Peatland. Wetlands. 36(6):1119-1130.
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2016. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668.
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2017. Forest phenology and a warmer climate – growing season extension in relation to climatic provenance. Global Change Biology. 18:2008–2025.
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2012. Intermediate-scale community-level flux of CO2 and CH4 in a Minnesota peatland: putting the SPRUCE project in a global context. Biogeochemistry. 129(3):255-272.
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2016. Attaining whole-ecosystem warming using air and deep-soil heating methods with an elevated CO2 atmosphere. Biogeosciences. 14:861-883.
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2017. A method for experimental heating of intact soil profiles for application to climate change experiments. Global Change Biology. 17:1083–1096.
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2011. Rapid Net Carbon Loss From a Whole‐Ecosystem Warmed Peatland. AGU Advances. 1(3)
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2020. Gaseous mercury fluxes in peatlands and the potential influence of climate change. Atmospheric Environment. 154:247-259.
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2017. Long-term carbon and nitrogen dynamics at SPRUCE revealed through stable isotopes in peat profiles. Biogeosciences. 14(9):2481-2494.
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2017. Soil thermal dynamics, snow cover, and frozen depth under five temperature treatments in an ombrotrophic bog: Constrained forecast with data assimilation. Journal of Geophysical Research: Biogeosciences. 122:2046-2063.
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2017. Fine-root growth in a forested bog is seasonally dynamic, but shallowly distributed in nutrient-poor peat. Plant and Soil. 424:123–143.
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2018. Needle age and season influence photosynthetic temperature response and total annual carbon uptake in mature Picea mariana trees. Annals of Botany. 116:821-832.
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2015. Forecasting responses of a northern peatland carbon cycle to elevated CO2 and a gradient of experimental warming. Journal of Geophysical Research: Biogeosciences. 123(3):1057-1071.
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2018. The Sphagnum microbiome: new insights from an ancient plant lineage. New Phytologist. 211(1):57-64.
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2016. Near-real-time environmental monitoring and large-volume data collection over slow communication links. Geoscientific Instrumentation, Methods and Data Systems. 7(4):289-295.
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2018. A comprehensive data acquisition and management system for an ecosystem-scale peatland warming and elevated CO2 experiment. Geoscientific Instrumentation, Methods and Data Systems. 4(2):203-213.
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2015. Microbial Metabolic Potential for Carbon Degradation and Nutrient (Nitrogen and Phosphorus) Acquisition in an Ombrotrophic Peatland. Applied and Environmental Microbiology. 80(11):3531-3540.
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2014. Microbial Community Stratification Linked to Utilization of Carbohydrates and Phosphorus Limitation in a Boreal Peatland at Marcell Experimental Forest, Minnesota, USA. Applied and Environmental Microbiology. 80(11):3518-3530.
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2014.