COS 78-1 - Mapping climate change exposure in a rugged Mediterranean-climate landscape

Thursday, August 11, 2016: 1:30 PM
Grand Floridian Blrm A, Ft Lauderdale Convention Center
Ian M. McCullough1, Frank W. Davis2, John R. Dingman3, Lorraine E. Flint4, Alan L. Flint4, Josep M. Serra-Diaz5, Alexandra D. Syphard6, Max A. Moritz7, Lee Hannah8 and Janet Franklin9, (1)Bren School of Environmental Science & Management, University of California, Santa Barbara, Santa Barbara, CA, (2)National Center for Ecological Analysis and Synthesis, Santa Barbara, CA, (3)Environmental Science, Policy and Management, University of California, Berkeley, CA, (4)U.S. Geological Survey California Water Science Center, Sacramento, CA, (5)Harvard Forest, Petersham, MA, (6)Conservation Biology Institute, La Mesa, CA, (7)Department of Environmental Science, Policy and Management, University of California, Berkeley, Berkeley, CA, (8)The Betty and Gordon Moore Center for Science and Oceans, Conservation International, Santa Barbara, CA, (9)School of Geographical Sciences and Urban Planning, Arizona State University, Tempe, AZ
Background/Question/Methods

Predicting climate-driven species’ range shifts depends substantially on species’ exposure to climate change. Mountain landscapes contain a wide range of topoclimates and soil characteristics that are thought to mediate range shifts and buffer species’ exposure. Quantifying fine-scale patterns of exposure across mountainous terrain is a key step in understanding vulnerability of species to regional climate change. We demonstrated a transferable, flexible approach for mapping climate change exposure in a moisture-limited, mountainous California landscape across 4 climate change projections under phase 5 of the Coupled Model Intercomparison Project (CMIP5) for mid-(2040–2069) and end-of-century (2070–2099). We produced a 149-year dataset (1951–2099) of modeled climatic water deficit (CWD), which is strongly associated with plant distributions, at 30-m resolution to map climate change exposure in the Tehachapi Mountains, California, USA. We defined climate change exposure in terms of departure from the 1951–1980 mean and historical range of variability in CWD in individual years and 3-year moving windows.

Results/Conclusions

Climate change exposure was generally greatest at high elevations across all future projections, though we encountered moderate topographic buffering on poleward-facing slopes. Historically dry lowlands demonstrated the least exposure to climate change. In moisture-limited, Mediterranean-climate landscapes, high elevations may experience the greatest exposure to climate change in the 21st century. High elevation species may thus be especially vulnerable to continued climate change as habitats shrink and historically energy-limited locations become increasingly moisture-limited in the future.