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Burning trees in frozen soil: Simulating fire, vegetation, soil, and hydrology in the boreal forests of Alaska

Author

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  • Lucash, Melissa S.
  • Marshall, Adrienne M.
  • Weiss, Shelby A.
  • McNabb, John W.
  • Nicolsky, Dmitry J.
  • Flerchinger, Gerald N.
  • Link, Timothy E.
  • Vogel, Jason G.
  • Scheller, Robert M.
  • Abramoff, Rose Z.
  • Romanovsky, Vladimir E.

Abstract

Boreal ecosystems account for 29% of the world's total forested area and contain more carbon than any other terrestrial biome. Over the past 60 years, Alaska has warmed twice as rapidly as the contiguous U.S. and wildfire activity has increased, including the number of fires, area burned, and frequency of large wildfire seasons. These recent and rapid changes in climate and wildfire have implications for future vegetation composition, structure, and biomass in interior Alaska, given that the vegetation is highly dependent on active layer thickness, soil moisture, organic layer depth, and plant-available nutrients. Here we developed a new succession extension (DGS) of the LANDIS-II forest landscape model which integrates a vegetation dynamics model (NECN) with a soil carbon model (DAMM-McNiP), a hydrologic model (SHAW), and a deep soil profile permafrost model (GIPL) in a spatially-explicit framework. DGS Succession uses the algorithms in the NECN Succession extension of LANDIS-II to simulate growth, mortality and reproduction of vegetation but has three major improvements. First, the simple bucket model in NECN was replaced with a physically-based model (SHAW) that simulates energy and water fluxes (e.g. snow depth, evapotranspiration, soil moisture) at multiple levels in the canopy and soil. Second, the active, slow, and passive soil pools in NECN were replaced by seven soil pools that are measurable in the field, with carbon and nitrogen dynamics dictated by DAMM-McNiP. Finally, soil temperature and soil moisture are simulated only at one depth in NECN, but in DGS, soil temperature (and hence permafrost dynamics) are simulated at as many as 50 user-defined depths down to 4 m with SHAW and 75 m with GIPL. During the initial calibration phase, DGS was applied at three inventory sites at the Bonanza Creek Long Term Ecological Research area in Interior Alaska where climate forcings, species biomass, soil temperature, and/or soil moisture were available. For the landscape-scale simulations, DGS was run with the SCRPPLE fire extension of LANDIS-II under two scenarios of climate using a ∼400,000 ha landscape that included the inventory sites. Across all three sites, DGS generally captured the variation in soil moisture and temperature across depths, seasons, and years reasonably well, though there were some discrepancies at each site. DGS had better agreement with field measurements of soil moisture and temperature than its predecessor NECN which produced unrealistically low soil moisture and unrealistically high seasonal fluctuations in soil temperature. At the landscape scale, ignitions, area burned, and soil temperature increased under climate change, as expected, while soil moisture was relatively unchanged across climate scenarios. Biomass tended to decline under climate change, which differs from other modeling studies in this region but is consistent with the browning trends observed from remote sensing data. Simulating climate, vegetation succession, hydrology, permafrost, carbon and nutrient cycling, and wildfire in an integrated, spatially-explicit framework like LANDIS-II will allow us to disentangle the drivers and ecosystem responses in this rapidly changing ecosystem, as well as other forested systems with complex hydrologic, biochemical, cryospheric, and vegetation feedbacks.

Suggested Citation

  • Lucash, Melissa S. & Marshall, Adrienne M. & Weiss, Shelby A. & McNabb, John W. & Nicolsky, Dmitry J. & Flerchinger, Gerald N. & Link, Timothy E. & Vogel, Jason G. & Scheller, Robert M. & Abramoff, Ro, 2023. "Burning trees in frozen soil: Simulating fire, vegetation, soil, and hydrology in the boreal forests of Alaska," Ecological Modelling, Elsevier, vol. 481(C).
    • Handle: RePEc:eee:ecomod:v:481:y:2023:i:c:s0304380023000959
    DOI: 10.1016/j.ecolmodel.2023.110367
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    References listed on IDEAS

    as
    1. Seidl, Rupert & Rammer, Werner & Scheller, Robert M. & Spies, Thomas A., 2012. "An individual-based process model to simulate landscape-scale forest ecosystem dynamics," Ecological Modelling, Elsevier, vol. 231(C), pages 87-100.
    2. V. E. Romanovsky & T. E. Osterkamp, 2000. "Effects of unfrozen water on heat and mass transport processes in the active layer and permafrost," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 11(3), pages 219-239, July.
    3. D. A. Walker & G. J. Jia & H. E. Epstein & M. K. Raynolds & F. S. Chapin III & C. Copass & L. D. Hinzman & J. A. Knudson & H. A. Maier & G. J. Michaelson & F. Nelson & C. L. Ping & V. E. Romanovsky & , 2003. "Vegetation‐soil‐thaw‐depth relationships along a low‐arctic bioclimate gradient, Alaska: synthesis of information from the ATLAS studies," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 14(2), pages 103-123, April.
    4. Armatas, Christopher A. & Campbell, Robert M. & Watson, Alan E. & Borrie, William T. & Christensen, Neal & Venn, Tyron J., 2018. "An integrated approach to valuation and tradeoff analysis of ecosystem services for national forest decision-making," Ecosystem Services, Elsevier, vol. 33(PA), pages 1-18.
    5. Sander Veraverbeke & Brendan M. Rogers & Mike L. Goulden & Randi R. Jandt & Charles E. Miller & Elizabeth B. Wiggins & James T. Randerson, 2017. "Lightning as a major driver of recent large fire years in North American boreal forests," Nature Climate Change, Nature, vol. 7(7), pages 529-534, July.
    6. Ketil Isaksen & Rune Strand Ødegård & Bernd Etzelmüller & Christin Hilbich & Christian Hauck & Herman Farbrot & Trond Eiken & Hans Olav Hygen & Tobias Florian Hipp, 2011. "Degrading Mountain Permafrost in Southern Norway: Spatial and Temporal Variability of Mean Ground Temperatures, 1999–2009," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 22(4), pages 361-377, October.
    7. Scott Jasechko & Zachary D. Sharp & John J. Gibson & S. Jean Birks & Yi Yi & Peter J. Fawcett, 2013. "Terrestrial water fluxes dominated by transpiration," Nature, Nature, vol. 496(7445), pages 347-350, April.
    8. Sturtevant, Brian R. & Scheller, Robert M. & Miranda, Brian R. & Shinneman, Douglas & Syphard, Alexandra, 2009. "Simulating dynamic and mixed-severity fire regimes: A process-based fire extension for LANDIS-II," Ecological Modelling, Elsevier, vol. 220(23), pages 3380-3393.
    9. T. F. Keenan & X. Luo & M. G. Kauwe & B. E. Medlyn & I. C. Prentice & B. D. Stocker & N. G. Smith & C. Terrer & H. Wang & Y. Zhang & S. Zhou, 2021. " RETRACTED ARTICLE: A constraint on historic growth in global photosynthesis due to increasing CO2," Nature, Nature, vol. 600(7888), pages 253-258, December.
    10. Soetaert, Karline & Petzoldt, Thomas, 2010. "Inverse Modelling, Sensitivity and Monte Carlo Analysis in R Using Package FME," Journal of Statistical Software, Foundation for Open Access Statistics, vol. 33(i03).
    11. Scheller, Robert M. & Domingo, James B. & Sturtevant, Brian R. & Williams, Jeremy S. & Rudy, Arnold & Gustafson, Eric J. & Mladenoff, David J., 2007. "Design, development, and application of LANDIS-II, a spatial landscape simulation model with flexible temporal and spatial resolution," Ecological Modelling, Elsevier, vol. 201(3), pages 409-419.
    12. Scheller, Robert & Kretchun, Alec & Hawbaker, Todd J. & Henne, Paul D., 2019. "A landscape model of variable social-ecological fire regimes," Ecological Modelling, Elsevier, vol. 401(C), pages 85-93.
    13. Rebecca C. Scholten & Randi Jandt & Eric A. Miller & Brendan M. Rogers & Sander Veraverbeke, 2021. "Overwintering fires in boreal forests," Nature, Nature, vol. 593(7859), pages 399-404, May.
    14. Foster, Adrianna C. & Armstrong, Amanda H. & Shuman, Jacquelyn K. & Shugart, Herman H. & Rogers, Brendan M. & Mack, Michelle C. & Goetz, Scott J. & Ranson, K. Jon, 2019. "Importance of tree- and species-level interactions with wildfire, climate, and soils in interior Alaska: Implications for forest change under a warming climate," Ecological Modelling, Elsevier, vol. 409(C), pages 1-1.
    15. Scheller, Robert M. & Hua, Dong & Bolstad, Paul V. & Birdsey, Richard A. & Mladenoff, David J., 2011. "The effects of forest harvest intensity in combination with wind disturbance on carbon dynamics in Lake States Mesic Forests," Ecological Modelling, Elsevier, vol. 222(1), pages 144-153.
    16. W. Matt Jolly & Mark A. Cochrane & Patrick H. Freeborn & Zachary A. Holden & Timothy J. Brown & Grant J. Williamson & David M. J. S. Bowman, 2015. "Climate-induced variations in global wildfire danger from 1979 to 2013," Nature Communications, Nature, vol. 6(1), pages 1-11, November.
    17. Kenji Yoshikawa & Larry D. Hinzman, 2003. "Shrinking thermokarst ponds and groundwater dynamics in discontinuous permafrost near council, Alaska," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 14(2), pages 151-160, April.
    18. T. E. Osterkamp & V. E. Romanovsky, 1999. "Evidence for warming and thawing of discontinuous permafrost in Alaska," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 10(1), pages 17-37, January.
    19. Valerie A. Barber & Glenn Patrick Juday & Bruce P. Finney, 2000. "Reduced growth of Alaskan white spruce in the twentieth century from temperature-induced drought stress," Nature, Nature, vol. 405(6787), pages 668-673, June.
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