LTER: The Role of Biogeochemical and Community Openness in Governing Arctic Ecosystem Response to Climate Change and Disturbance
March 2011 - April 2021
- NSF Long Term Ecological REsearch
The Arctic is one of the most rapidly warming regions on Earth. Responses to this warming involve acceleration of processes common to other ecosystems around the world (e.g., shifts in plant community composition) and changes to processes unique to the Arctic (e.g., carbon loss from permafrost thaw). The objectives of the Arctic Long-Term Ecological Research (LTER) Project for 2017-2023 are to use the concepts of biogeochemical and community “openness” and “connectivity” to understand the responses of arctic terrestrial and freshwater ecosystems to climate change and disturbance. These objectives will be met through continued long-term monitoring of changes in undisturbed terrestrial, stream, and lake ecosystems in the vicinity of Toolik Lake, Alaska, observations of the recovery of these ecosystems from natural and imposed disturbances, maintenance of existing long-term experiments, and initiation of new experimental manipulations. Based on these data, carbon and nutrient budgets and indices of species composition will be compiled for each component of the arctic landscape to compare the biogeochemistry and community dynamics of each ecosystem in relation to their responses to climate change and disturbance and to the propagation of those responses across the landscape. The Arctic LTER is a collaborative partnership between 5 Principle Investigators (including Budy) at academic units located at different universities and a conservative estimate of 28 secondary and very interdisciplinary Co-Principle investigators (and their students and staff) housed at 28 other academic units. The proposed research will compare key ecosystems of the Arctic to determine how their degree of openness governs their responses to climate change and acute disturbance such as fire and surface slumping associated with permafrost thaw. The proposed research will also determine how the responses to climate change and disturbance are mediated by landscape connectivity and the movement of nutrients, organic carbon, and organisms across arctic landscapes, and how that movement is facilitated or impeded by the degree of openness of the ecosystems.
|Research Publications||Publication Date|
|Budy, P. and C. Luecke. 2014. Understanding how lake populations of Arctic char are structured and function with special consideration of the potential effects of climate change: a multi-faceted approach. Oecologia DOI 10.1007/s00442-014-2993-8. USGS FSP: SPDS: IP-053259. | Abstract||June 2014|
|Budy, P. 2014. Arctic Lakes: Spring 2014 update and new direction. Arctic Long Term Ecological Research, 25-28. February, 2014, Woods Hole, Massachusetts.||February 2014|
|Budy, P. , A. Giblin, G. Kling, D. White, and C. Luecke. 2018. Understanding the indirect effects of climate change on pristine arctic lakes and char; delayed, multi-trophic level response to a long-term, low-level fertilization experiment. Oral Presentation. Annual Meeting of the Western Division of the American Fisheries Society, May 22-25, 2018, Anchorage, AK, USA.||May 2018|
Budy, P. G.P. Thiede, A. Giblin, A. Messenger, G. Kling, B. Crump, and N.R Christman. 2020. Evaluating the impact of a warmer climate on the aquatic ecology and fish of arctic lakes
via thermokarst disturbance. Western Division, American Fisheries Society Conference, Vancouver, B.C. , Canada. April 13-16, 2020.
The climate is changing faster in arctic Alaska than anywhere else on earth, and warming temperatures are having both direct and indirect effects on lakes and their biota.
|Budy, P., C. Luecke, and G.P. Thiede. 2011. Resources allocation among arctic char in closed arctic lakes: implications for population structure and regulation. Poster Presentation. American Fisheries Society, National Meeting, August 19-23, 2012, Minneapolis, MN.||August 2012|