GC31C-1202
The Post-Glacial Species Velocity of Picea glauca following the Last Glacial Maximum in Alaska.

Wednesday, 16 December 2015
Poster Hall (Moscone South)
Bailey Danielle Morrison1, Joseph Napier1, Ryan Kelly2, Bo Li1, Katy Heath1, Barbara Hug1, Fengsheng Hu3 and Jonathan A Greenberg4, (1)University of Illinois at Urbana Champaign, Urbana, IL, United States, (2)university of illinois, Urbana, IL, United States, (3)University of Illinois, Department of Plant Biology, Urbana, IL, United States, (4)University of Illinois at Urbana Champaign, Department of Geography and Geographic Information Science, Urbana, IL, United States
Abstract:
Anthropogenic climate change is leading to dramatic fluctuations to Earth’s biodiversity that has not been observed since past interglacial periods. There is rising concern that Earth’s warming climate will have significant impacts to current species ranges and the ability of a species to persist in a rapidly changing environment. The paleorecord provides information on past species distributions in relation to climate change, which can illuminate the patterns of potential future distributions of species. Particularly in areas where there are multiple potential limiting factors on a species’ range, e.g. temperature, radiation, and evaporative demand, the spatial patterns of species migrations may be particularly complex. In this study, we assessed the change in the distributions of white spruce (Picea glauca) from the Last Glacial Maxima (LGM) to present-day for the entire state of Alaska. To accomplish this, we created species distribution models (SDMs) calibrated from modern vegetation data and high-resolution, downscaled climate surfaces at 60m. These SDMs were applied to downscaled modern and paleoclimate surfaces to produce estimated ranges of white spruce during the LGM and today. From this, we assessed the “species velocity”, the rate at which white spruce would need to migrate to keep pace with climate change, with the goal of determining whether the expansion from the LGM to today originated from microclimate refugia. Higher species velocities indicate locations where climate changed drastically and white spruce would have needed to migrate rapidly to persist and avoid local extinction. Conversely, lower species velocities indicated locations where the local climate was changing less rapidly or was within the center of the range of white spruce, and indicated locations where white spruce distributions were unlikely to have changed significantly. Our results indicate the importance of topographic complexity in buffering the effects of climate change, particularly near the edges of the species’ range.