Long-term experimental warming and nutrient additions increase productivity in tall deciduous shrub tundra

TitleLong-term experimental warming and nutrient additions increase productivity in tall deciduous shrub tundra
Publication TypeJournal Article
Year of Publication2014
AuthorsDeMarco J., Mack M.C, Bret-Harte MS, Burton M., Shaver GR
Date PublishedJun
ISBN Number2150-8925
Accession NumberISI:000338925000006
Keywordsalaskan tundra, altered environment, arctic, arctic dwarf shrubs, carbon pools, carbon storage, climate change, deciduous shrubs, environmental-change, gas-exchange, growth-responses, manipulated warming, meta-analysis, nitrogen pools, northern alaska, nutrient additions, plant functional types, simulating climatic-change, tundra

Warming Arctic temperatures can drive changes in vegetation structure and function directly by stimulating plant growth or indirectly by stimulating microbial decomposition of organic matter and releasing more nutrients for plant uptake and growth. The arctic biome is currently increasing in deciduous shrub cover and this increase is expected to continue with climate warming. However, little is known how current deciduous shrub communities will respond to future climate induced warming and nutrient increase. We examined the plant and ecosystem response to a long-term (18 years) nutrient addition and warming experiment in an Alaskan arctic tall deciduous shrub tundra ecosystem to understand controls over plant productivity and carbon (C) and nitrogen (N) storage in shrub tundra ecosystems. In addition, we used a meta-analysis approach to compare the treatment effect size for aboveground biomass among seven long-term studies conducted across multiple plant community types within the Arctic. We found that biomass, productivity, and aboveground N pools increased with nutrient additions and warming, while species diversity decreased. Both nutrient additions and warming caused the dominant functional group, deciduous shrubs, to increase biomass and proportional C and N allocation to aboveground stems but decreased allocation to belowground stems. For all response variables except soil C and N pools, effects of nutrients plus warming were largest. Soil C and N pools were highly variable and we could not detect any response to the treatments. The biomass response to warming and fertilization in tall deciduous shrub tundra was greater than moist acidic and moist non-acidic tundra and more similar to the biomass response of wet sedge tundra. Our data suggest that in a warmer and more nutrient-rich Arctic, tall deciduous shrub tundra will have greater total deciduous shrub biomass and a higher proportion of woody tissue that has a longer residence time, with a lower proportion of C and N allocated to belowground stems.

Short TitleEcosphereEcosphere
Alternate JournalEcosphere