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Ecosystems

, Volume 14, Issue 3, pp 489–502 | Cite as

Tracking Soil Temperature and Moisture in a Multi-Factor Climate Experiment in Temperate Grassland: Do Climate Manipulation Methods Produce their Intended Effects?

  • Cameron N. CarlyleEmail author
  • Lauchlan H. Fraser
  • Roy Turkington
Article

Abstract

Passive open-top chambers (OTCs) and rainout shelters (RSs) have been used for over two decades to manipulate temperature and water availability in experiments on plant communities. These types of manipulations have been independently evaluated; however, as experiments become more complex and multiple factors are evaluated the potential for unknown or undesirable treatment effects increases. We present the effects of temperature manipulations (with OTCs), water manipulations (with RSs and water additions), and a clipping treatment, implemented in a fully factorial design, on soil moisture and temperature over 2 years in a temperate grassland. Temperature was increased 0.2°C by OTCs. Soil volumetric water content was reduced 3% by RSs and increased 2% by watering. However, clipping vegetation, treatment interactions, and weather conditions also affected soil temperature and moisture. For example, in OTCs RSs increased the temperature an additional 0.4°C, watering lowered it 0.4°C, and clipping raised temperature 2°C. Similarly, changes in soil moisture due to the RSs decreased VWC by 3% and increased 1% by clipping whereas soil moisture due to watering was reduced 1% by the OTCs and clipping. We also found that OTCs are more effective at raising temperatures on cooler days when soil temperatures are below 16.3°C. Our results suggest that all treatment types generally affect soil variables in predicable ways, but use of such devices should be adopted with caution, as they do not act independently, or exclusively, on the target variables.

Keywords

open-top chamber rainout shelter climate change soil volumetric water content clipping disturbance 

Notes

Acknowledgments

The research was supported with an NSERC Discovery Grant, a Canadian Foundation for Innovation Grant, and a BC Forest Science Program Grant to LHF. CNC was supported with an NSERC IPS in collaboration with the Grasslands Conservation Council of BC, a UBC Graduate Fellowship and a Pacific Century scholarship from the government of British Columbia. Comments from Doug Frank and anonymous reviewers improved this manuscript. We thank Brandy Ludwig, Amber Greenall, Montana Burgess, Eleanor Bassett, Lisa DeSandoli, Amy Bitz, Jessica Gosling, and Anna-Marie Pellet who provided assistance maintaining the experiment. Don Thompson, at Agriculture and Agri-food Canada, and the BC Ministry of Environment helped with logistics and allowed site access.

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Copyright information

© Springer Science+Business Media, LLC 2011

Authors and Affiliations

  • Cameron N. Carlyle
    • 1
    • 2
    Email author
  • Lauchlan H. Fraser
    • 2
  • Roy Turkington
    • 1
  1. 1.Department of Botany and Biodiversity Research CentreUniversity of British ColumbiaVancouverCanada
  2. 2.Department of Natural Resource SciencesThompson Rivers UniversityKamloopsCanada

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