Title:

Plot-level field data and model simulation results, archived to accompany Turner et al. manuscript; reports data from summer 2017 sampling of short-interval fires that burned during summer 2016 in Greater Yellowstone

Author(s):

Turner, Monica G.; Braziunas, Kristin H.; Hansen, Winslow D.; Harvey, Brian J.

Publication Year:

2019

How to Cite:

If you use these data in a publication, presentation, or other research product please use the following citation:

Turner, Monica G.; Braziunas, Kristin H.; Hansen, Winslow D.; Harvey, Brian J. 2019. Plot-level field data and model simulation results, archived to accompany Turner et al. manuscript; reports data from summer 2017 sampling of short-interval fires that burned during summer 2016 in Greater Yellowstone. Environmental Data Initiative. https://doi.org/10.6073/pasta/a1b7791376a04ce8c6ea9043547bb6af

Abstract:

Subalpine forests in the northern Rocky Mountains have been resilient to stand-replacing fires that historically burned at 100–300-yr intervals. Fire intervals are projected to decline drastically as climate warms, and forests that reburn before recovering from previous fire may lose their ability to rebound. We studied recent fires in Greater Yellowstone (Wyoming, USA) and asked whether short-interval (less than 30 yrs) stand-replacing fires can erode lodgepole pine (Pinus contorta var. latifolia) forest resilience via increased burn severity, reduced early postfire tree regeneration, reduced carbon stocks, and slower carbon recovery. During 2016, fires reburned young lodgepole pine forests that regenerated after wildfires in 1988 and 2000. During 2017, we sampled 0.25-ha plots in stand-replacing reburns (n=18) and nearby young forests that did not reburn (n=9). We also simulated stand development with and without reburns to assess carbon recovery trajectories. Nearly all prefire biomass was combusted ("crown fire plus") in some reburns in which prefire trees were dense and small (≤ 4 cm basal diameter). Postfire tree seedling density was reduced six-fold relative to the previous (long-interval) fire, and high-density stands (greater than 40,000 stems ha-1) were converted to sparse stands (less than 1,000 stems ha-1). In reburns, coarse wood biomass and aboveground carbon stocks were reduced by 65% and 62%, respectively, relative to areas that did not reburn. Increased carbon loss plus sparse tree regeneration delayed simulated carbon recovery by greater than 150 yrs. Forests did not transition to nonforest, but extreme burn severity and reduced tree recovery foreshadow an erosion of forest resilience.

Keywords:

biota; Fire; Fire ecology; Berry Fire; Maple Fire; North Fork Fire; Huck Fire; Glade Fire; lodgepole pine; aspen; burn severity; disturbance; University of Wyoming-National Park Service Research Station; AMK Ranch; Joint Fire Science Program; JFSP; Wyoming; Yellowstone National Park; Grand Teton National Park

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