Journal list menu
It takes a few to tango: changing climate and fire regimes can cause regeneration failure of two subalpine conifers
Corresponding Author
Winslow D. Hansen
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
E-mail: [email protected]Search for more papers by this authorKristin H. Braziunas
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
Search for more papers by this authorWerner Rammer
Department of Forest and Soil Sciences, Institute of Silviculture, University of Natural Resources and Life Sciences (BOKU), Vienna, Austria
Search for more papers by this authorRupert Seidl
Department of Forest and Soil Sciences, Institute of Silviculture, University of Natural Resources and Life Sciences (BOKU), Vienna, Austria
Search for more papers by this authorMonica G. Turner
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
Search for more papers by this authorCorresponding Author
Winslow D. Hansen
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
E-mail: [email protected]Search for more papers by this authorKristin H. Braziunas
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
Search for more papers by this authorWerner Rammer
Department of Forest and Soil Sciences, Institute of Silviculture, University of Natural Resources and Life Sciences (BOKU), Vienna, Austria
Search for more papers by this authorRupert Seidl
Department of Forest and Soil Sciences, Institute of Silviculture, University of Natural Resources and Life Sciences (BOKU), Vienna, Austria
Search for more papers by this authorMonica G. Turner
Department of Integrative Biology, University of Wisconsin-Madison, Madison, Wisconsin, 53706 USA
Search for more papers by this authorAbstract
Environmental change is accelerating in the 21st century, but how multiple drivers may interact to alter forest resilience remains uncertain. In forests affected by large high-severity disturbances, tree regeneration is a resilience linchpin that shapes successional trajectories for decades. We modeled stands of two widespread western U.S. conifers, Douglas-fir (Pseudotsuga menziesii var. glauca), and lodgepole pine (Pinus contorta var. latifolia), in Yellowstone National Park (Wyoming, USA) to ask (1) What combinations of distance to seed source, fire return interval, and warming-drying conditions cause postfire tree-regeneration failure? (2) If postfire tree regeneration was successful, how does early tree density differ under future climate relative to historical climate? We conducted a stand-level (1 ha) factorial simulation experiment using the individual-based forest process model iLand to identify combinations of fire return interval (11–100 yr), distance to seed source (50–1,000 m), and climate (historical, mid-21st century, late-21st century) where trees failed to regenerate by 30-yr postfire. If regeneration was successful, we compared stand densities between climate periods. Simulated postfire regeneration were surprisingly resilient to changing climate and fire drivers. Douglas-fir regeneration failed more frequently (55%) than lodgepole pine (28% and 16% for non-serotinous and serotinous stands, respectively). Distance to seed source was an important driver of regeneration failure for Douglas-fir and non-serotinous lodgepole pine; regeneration never failed when stands were 50 m from a seed source and nearly always failed when stands were 1 km away. Regeneration of serotinous lodgepole pine only failed when fire return intervals were ≤20 yr and stands were far (1 km) from a seed source. Warming climate increased regeneration success for Douglas-fir but did not affect lodgepole pine. If regeneration was successful, postfire density varied with climate. Douglas-fir and serotinous lodgepole pine regeneration density both increased under 21st-century climate but in response to different climate variables (growing season length vs. cold limitation). Results suggest that, given a warmer future with larger and more frequent fires, a greater number of stands that fail to regenerate after fires combined with increasing density in stands where regeneration is successful could produce a more coarse-grained forest landscape.
Supporting Information
Filename | Description |
---|---|
ecy2181-sup-0001-AppendixS1.pdfPDF document, 24.4 KB | |
ecy2181-sup-0002-AppendixS2.pdfPDF document, 66.5 KB |
Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.
Literature Cited
- Abatzoglou, J. T., and T. J. Brown. 2012. A comparison of statistical downscaling methods suited for wildfire applications. International Journal of Climatology 32: 772–780.
- Abatzoglou, J. T., and A. P. Williams. 2016. Impact of anthropogenic climate change on wildfire across western US forests. Proceedings of the National Academy of Sciences USA 113: 11770–11775.
- Bartlein, P. J., C. Whitlock, and S. L. Shafer. 1997. Future climate in the Yellowstone National Park region and its potential impact on vegetation. Conservation Biology 11: 782–792.
- Barton, K. 2016. MuMIn: Multi-Model inference. https://cran.r-project.org/web/packages/MuMIn/index.html
- Bates, D., M. Mächler, B. Bolker, and S. Walker. 2015. Fitting linear mixed-effects models using lme4. Journal of Statistical Software 67: 1–48.
- Batllori, E., J. J. Camarero, J. M. Ninot, and E. Gutiérrez. 2009. Seedling recruitment, survival and facilitation in alpine Pinus uncinata tree line ecotones. Implications and potential responses to climate warming. Global Ecology and Biogeography 18: 460–472.
- Bell, D. M., J. B. Bradford, and W. K. Lauenroth. 2014. Early indicators of change: divergent climate envelopes between tree life stages imply range shifts in the western United States. Global Ecology and Biogeography 23: 168–180.
- Benkman, C. W., and A. M. Siepielski. 2004. A keystone selective agent? Pine squirrels and the frequency of serotiny in lodgepole pine. Ecology 85: 2082–2087.
- Bowman, D. M. J. S., G. L. W. Perry, and J. B. Marston. 2015. Feedbacks and landscape-level vegetation dynamics. Trends in Ecology and Evolution 30: 255–260.
- Bowman, D. M. J. S., G. J. Williamson, L. D. Prior, and B. P. Murphy. 2016. The relative importance of intrinsic and extrinsic factors in the decline of obligate seeder forests. Global Ecology and Biogeography 25: 1166–1172.
- Brown, C. D., and J. F. Johnstone. 2012. Once burned, twice shy: Repeat fires reduce seed availability and alter substrate constraints on Picea mariana regeneration. Forest Ecology and Management 266: 34–41.
- Buma, B. 2015. Disturbance interactions: characterization, prediction, and the potential for cascading effects. Ecosphere 6: 1–15.
- Buma, B., C. D. Brown, D. C. Donato, J. B. Fontaine, and J. F. Johnstone. 2013. The impacts of changing disturbance regimes on serotinous plant populations and communities. BioScience 63: 866–876.
- Burnham, K. P., and D. R. Anderson. 2002. Model selection and multimodel inference. Second edition. Springer-Verlag, New York, New York, USA.
- Burns, R. M., and B. H. Honkala. 1990. Silvics manual volume 1-conifers and volume 2-hardwoods. Second edition. U.S. Department of Agriculture, Forest Service, Washington, D.C.
- Causley, C. L., W. Fowler, B. B. Lamont, and T. He. 2016. Fitness benefits of serotiny in fire- and drought-prone environments. Plant Ecology 217: 779.
- Chambers, M. E., P. J. Fornwalt, S. L. Malone, and M. A. Battaglia. 2016. Patterns of conifer regeneration following high severity wildfire in ponderosa pine dominated forests of the Colorado Front Range. Forest Ecology and Management 378: 57–67.
- Chazdon, R. L., P. H. S. Brancalion, L. Laestadius, A. Bennett-Curry, K. Buckingham, C. Kumar, J. Moll-Rocek, I. C. G. Vieira, and S. J. Wilson. 2016. When is a forest a forest? Forest concepts and definitions in the era of forest and landscape restoration. Ambio 45: 538–550.
- Chmura, D. J., P. D. Anderson, G. T. Howe, C. A. Harrington, J. E. Halofsky, D. L. Peterson, D. C. Shaw, and J. B. St.Clair. 2011. Forest responses to climate change in the northwestern United States: ecophysiological foundations for adaptive management. Forest Ecology and Management 261: 1121–1142.
- Clark, J. S., et al. 2016. The impacts of increasing drought on forest dynamics, structure, and biodiversity. Global Change Biology 22: 2329–2352.
- Clark, J. A., R. A. Loehman, and R. E. Keane. 2017. Climate changes and wildfire alter vegetation of Yellowstone National Park, but forest cover persists. Ecosphere 8: e01636.
- Coops, N. C., and R. H. Waring. 2011. A process-based approach to estimate lodgepole pine (Pinus contorta Dougl.) distribution in the Pacific Northwest under climate change. Climatic Change 105: 313–328.
- Copenhaver-Parry, P. E., B. N. Shuman, and D. B. Tinker. 2017. Toward an improved conceptual understanding of North American tree species distributions. Ecosphere 8: e01853.
- Crookston, N. L., G. E. Rehfeldt, G. E. Dixon, and A. R. Weiskittel. 2010. Addressing climate change in the forest vegetation simulator to assess impacts on landscape forest dynamics. Forest Ecology and Management 260: 1198–1211.
- Dakos, V., S. Kéfi, M. Rietkerk, E. H. van Nes, and M. Scheffer. 2011. Slowing down in spatially patterned ecosystems at the brink of collapse. American Naturalist 177: E153–E166.
- Despain, D. G. 1990. Yellowstone vegetation: consequences of environment and history in a natural setting. Roberts Rinehart Publishers, Boulder, Colorado, USA.
- Dietze, M. C. 2017. Ecological forecasting. Princeton University Press, Princeton, New Jersey, USA.
10.1515/9781400885459 Google Scholar
- Donato, D. C., B. J. Harvey, and M. G. Turner. 2016. Regeneration of montane forests 24 years after the 1988 Yellowstone fires: A fire-catalyzed shift in lower treelines? Ecosphere 7: e01410.
- Enright, N. J., J. B. Fontaine, B. B. Lamont, B. P. Miller, and V. C. Westcott. 2014. Resistance and resilience to changing climate and fire regime depend on plant functional traits. Journal of Ecology 102: 1572–1581.
- Enright, N. J., J. B. Fontaine, D. M. Bowman, R. A. Bradstock, and R. J. Williams. 2015. Interval squeeze: altered fire regimes and demographic responses interact to threaten woody species persistence as climate changes. Frontiers in Ecology and the Environment 13: 265–272.
- Ford, K. R., C. A. Harrington, S. Bansal, P. J. Gould, and J. B. St. Clair. 2016. Will changes in phenology track climate change? A study of growth initiation timing in coast Douglas-fir. Global Change Biology 22: 3712–3723.
- Franklin, J. F., and R. T. T. Forman. 1987. Creating landscape patterns by forest cutting: ecological consequences and principles. Landscape Ecology 1: 5–18.
- Franklin, J. F., et al. 2002. Disturbances and structural development of natural forest ecosystems with silvicultural implications, using Douglas-fir forests as an example. Forest Ecology and Management 155: 399–423.
- Gauthier, S., P. Bernier, T. Kuuluvainen, A. Z. Shvidenko, and D. G. Schepaschenko. 2015. Boreal forest health and global change. Science 349: 819–822.
- Ghazoul, J., and R. Chazdon. 2017. Degradation and recovery in changing forest landscapes: a multiscale conceptual framework. Annual Reviews of Environment and Resources 42: 1–28.
- Ghazoul, J., Z. Burivalova, J. Garcia-Ulloa, and L. A. King. 2015. Conceptualizing forest degradation. Trends in Ecology and Evolution 30: 622–632.
- Gray, L. K., and A. Hamann. 2013. Tracking suitable habitat for tree populations under climate change in western North America. Climatic Change 117: 289–303.
- Grimm, V., and U. Berger. 2016. Structural realism, emergence, and predictions in next-generation ecological modelling: synthesis from a special issue. Ecological Modelling 326: 177–187.
- Gustafson, E. J. 2013. When relationships estimated in the past cannot be used to predict the future: using mechanistic models to predict landscape ecological dynamics in a changing world. Landscape Ecology 28: 1429–1437.
- Hansen, A. J., and L. B. Phillips. 2015. Which tree species and biome types are most vulnerable to climate change in the US Northern Rocky Mountains? Forest Ecology and Management 338: 68–83.
- Hansen, W. D., W. H. Romme, A. Ba, and M. G. Turner. 2016. Shifting ecological filters mediate postfire expansion of seedling aspen (Populus tremuloides) in Yellowstone. Forest Ecology and Management 362: 218–230.
- Harvey, B. J., D. C. Donato, and M. G. Turner. 2016a. High and dry: post-fire tree seedling establishment in subalpine forests decreases with post-fire drought and large stand-replacing burn patches. Global Ecology and Biogeography 25: 655–669.
- Harvey, B. J., D. C. Donato, and M. G. Turner. 2016b. Drivers and trends in spatial patterns of burn severity in forests of the US Northern Rocky Mountains (1984–2010). Landscape Ecology 31: 2367–2383.
- He, T., J. G. Pausas, C. M. Belcher, D. W. Schwilk, and B. B. Lamont. 2012. Fire-adapted traits of Pinus arose in the fiery Cretaceous. New Phytologist 194: 751–759.
- Hirota, M., M. Holmgren, E. H. van Nes, and M. Scheffer. 2011. Global resilience of tropical forest and savanna to critical transitions. Science 334: 232–235.
- Hoffmann, W. A., E. L. Geiger, S. G. Gotsch, D. R. Rossatto, L. C. R. Silva, O. L. Lau, M. Haridasan, and A. C. Franco. 2012. Ecological thresholds at the savanna-forest boundary: How plant traits, resources and fire govern the distribution of tropical biomes. Ecology Letters 15: 759–768.
- Hughes, T. P., C. Linares, V. Dakos, I. A. van de Leemput, and E. H. van Nes. 2013. Living dangerously on borrowed time during slow, unrecognized regime shifts. Trends in Ecology and Evolution 28: 149–155.
- Inouye, D. W. 2000. The ecological and evolutionary significance of frost in the context of climate change. Ecology Letters 3: 457–463.
- Johnstone, J. F., and F. S. Chapin. 2006. Effects of soil burn severity on post-fire tree recruitment in boreal forest. Ecosystems 9: 14–31.
- Johnstone, J. F., L. Boby, E. Tissier, M. Mack, D. Verbyla, and X. Walker. 2009. Postfire seed rain of black spruce, a semiserotinous conifer, in forests of interior Alaska. Canadian Journal of Forest Research 39: 1575–1588.
- Johnstone, J. F., T. N. Hollingsworth, F. S. Chapin, and M. C. Mack. 2010. Changes in fire regime break the legacy lock on successional trajectories in Alaskan boreal forest. Global Change Biology 16: 1281–1295.
- Johnstone, J. F., et al. 2016. Changing disturbance regimes, ecological memory, and forest resilience. Frontiers in Ecology and the Environment 14: 369–378.
- Kashian, D. M., M. G. Turner, W. H. Romme, and C. G. Lorimer. 2005. Variability and convergence in stand structural development on a fire-dominated subalpine landscape. Ecology 86: 643–654.
- Keane, R. E., D. McKenzie, D. A. Falk, E. A. H. Smithwick, C. Miller, and L. K. B. Kellogg. 2015. Representing climate, disturbance, and vegetation interactions in landscape models. Ecological Modelling 309–310: 33–47.
- Keeley, J. E., G. Ne'eman, and C. J. Fotheringham. 1999. Immaturity risk in a fire-dependent pine. Journal of Mediterranean Ecology 1: 41–48.
- Keeley, J. E., C. J. Fotheringham, and M. Baer-Keeley. 2005. Determinants of postfire recovery and succession in mediterranean climate shrublands of California. Ecological Applications 15: 1515–1534.
- Kéfi, S., M. Rietkerk, C. L. Alados, Y. Pueyo, V. P. Papanastasis, A. Elaich, and P. C. de Ruiter. 2007. Spatial vegetation patterns and imminent desertification in Mediterranean arid ecosystems. Nature 449: 213–217.
- Kemp, K. B., P. E. Higuera, and P. Morgan. 2016. Fire legacies impact conifer regeneration across environmental gradients in the U.S. northern Rockies. Landscape Ecology 31: 619–636.
- Lamont, B. B., and N. J. Enright. 2000. Adaptive advantages of aerial seed banks. Plant Species Biology 15: 157–166.
10.1046/j.1442-1984.2000.00036.x Google Scholar
- Lamont, B. B., and T. He. 2017. Fire-proneness as a prerequisite for the evolution of fire-adapted traits. Trends in Plant Science 22: 278–288.
- Lamont, B. B., D. C. Maitre, R. M. Cowling, and N. J. Enright. 1991. Canopy seed storage in woody plants. Botanical Review 57: 277–317.
- Lenton, T. M., H. Held, E. Kriegler, J. W. Hall, W. Lucht, S. Rahmstorf, and H. J. Schellnhuber. 2008. Tipping elements in the Earth's climate system. Proceedings of the National Academy of Sciences USA 105: 1786–1793.
- Lindenmayer, D., C. Messier, and C. Sato. 2016. Avoiding ecosystem collapse in managed forest ecosystems. Frontiers in Ecology and the Environment 14: 561–568.
- Littell, J. S., D. L. Peterson, K. L. Riley, Y. Liu, and C. H. Luce. 2016. A review of the relationships between drought and forest fire in the United States. Global Change Biology 22: 1–17.
- Martínez-Vilalta, J., and F. Lloret. 2016. Drought-induced vegetation shifts in terrestrial ecosystems: the key role of regeneration dynamics. Global and Planetary Change 144: 94–108.
- Millar, C. I., and N. L. Stephenson. 2015. Temperate forest health in an era of emerging megadisturbance. Science 349: 823–826.
- Millspaugh, S. H., C. Whitlock, and P. J. Bartlein. 2000. Variations in fire frequency and climate over the past 17,000 yr in central Yellowstone National Park. Geology 28: 211–214.
- Paine, R. T., M. J. Tegner, and E. A. Johnson. 1998. Compounded perturbations yield ecological surprises. Ecosystems 1: 535–545.
- Pechony, O., and D. T. Shindell. 2010. Driving forces of global wildfires over the past millennium and the forthcoming century. Proceedings of the National Academy of Sciences USA 107: 19167–19170.
- Pedro, M. S., W. Rammer, and R. Seidl. 2015. Tree species diversity mitigates disturbance impacts on the forest carbon cycle. Oecologia 177: 619–630.
- Peters, D. P., R. A. Pielke, B. T. Bestelmeyer, C. D. Allen, S. Munson-mcgee, and K. M. Havstad. 2004. Cross-scale interactions, nonlinearities, and forecasting catastrophic events. Proceedings of the National Academy of Sciences USA 101: 15130–15135.
- Peters, D. P., B. T. Bestelmeyer, and M. G. Turner. 2007. Cross–scale interactions and changing pattern–process relationships: consequences for system dynamics. Ecosystems 10: 790–796.
- Power, M. J., C. Whitlock, and P. J. Bartlein. 2011. Postglacial fire, vegetation, and climate history across an elevational gradient in the Northern Rocky Mountains, USA and Canada. Quaternary Science Reviews 30: 2520–2533.
- R Core Team 2016. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. http://www.R-project.org/
- Renard, S. M., E. J. B. McIntire, and A. Fajardo. 2016. Winter conditions, not summer temperature, influence establishment of seedlings at white spruce alpine treeline in Eastern Quebec. Journal of Vegetation Science 27: 29–39.
- Reyer, C. P., et al. 2015. Forest resilience and tipping points at different spatio-temporal scales: approaches and challenges. Journal of Ecology 103: 5–15.
- Savage, M., and J. N. Mast. 2005. How resilient are southwestern ponderosa pine forests after crown fires? Canadian Journal of Forest Research 35: 967–977.
- Savage, M., J. N. Mast, and J. J. Feddema. 2013. Double whammy: high-severity fire and drought in ponderosa pine forests of the Southwest. Canadian Journal of Forest Research 583: 570–583.
- Scheffer, M. 2009. Critical transitions in nature and society. Princeton University Press, Princeton, New Jersey, USA.
10.1515/9781400833276 Google Scholar
- Scheffer, M., M. Hirota, M. Holmgren, E. H. van Nes, and F. S. Chapin. 2012. Thresholds for boreal biome transitions. Proceedings of the National Academy of Sciences USA 109: 21384–21389.
- Schoennagel, T., M. Turner, D. Kashian, and A. Fall. 2006. Influence of fire regimes on lodgepole pine stand age and density across the Yellowstone National Park (USA) landscape. Landscape Ecology 21: 1281–1296.
- Seidl, R. 2017. To model or not to model, that is no longer the question for ecologists. Ecosystems 20: 222–228.
- Seidl, R., et al. 2011. Modelling natural disturbances in forest ecosystems: a review. Ecological Modelling 222: 903–924.
- Seidl, R., W. Rammer, R. M. Scheller, and T. A. Spies. 2012. An individual-based process model to simulate landscape-scale forest ecosystem dynamics. Ecological Modelling 231: 87–100.
- Seidl, R., W. Rammer, and T. A. Spies. 2014. Disturbance legacies increase the resilience of forest ecosystem structure, composition, and functioning. Ecological Applications 24: 2063–2077.
- Seidl, R. D. C., K. F. Raffa. Donato, and M. G. Turner. 2016a. Spatial variability in tree regeneration after wildfire delays and dampens future bark beetle outbreaks. Proceedings of the National Academy of Sciences USA 113: 13075–13080.
- Seidl, R., T. A. Spies, D. L. Peterson, S. L. Stephens, and J. A. Hicke. 2016b. Searching for resilience: addressing the impacts of changing disturbance regimes on forest ecosystem services. Journal of Applied Ecology 53: 120–129.
- Seidl, R., et al. 2017. Forest disturbances under climate change. Nature Climate Change 7: 395–402.
- Simard, M., E. N. Powell, K. F. Raffa, and M. G. Turner. 2012. What explains landscape patterns of tree mortality caused by bark beetle outbreaks in Greater Yellowstone? Global Ecology and Biogeography 21: 556–567.
- Smith, P., et al. 2016. Biophysical and economic limits to negative CO2 emissions. Nature Climate Change 6: 42–50.
- Spies, T. A., et al. 2017. Using an agent-based model to examine forest management outcomes in a fire-prone landscape in Oregon, USA. Ecology and Society 22: art25.
- Staal, A., S. C. Dekker, M. Hirota, and E. H. van Nes. 2014. Synergisitc effects of drought and deforestation on the resilience of the south-eastern Amazon rainforest. Ecological Complexity 22: 65–75.
- Stevens-Rumann, C., and P. Morgan. 2016. Repeated wildfires alter forest recovery of mixed-conifer ecosystems. Ecological Applications 26: 1842–1853.
- Tepley, A. J., J. R. Thompson, H. E. Epstein, and K. J. Anderseon-Teixeira. 2017. Vulnerability to forest loss through altered postfire recovery dynamics in a warming climate in the Klamath Mountains. Global Change Biology 23: 4117–4132.
- Tercek, M., and A. Rodman. 2016. Forecasts of 21st century snowpack and implications for snowmobile and snowcoach use in Yellowstone National Park. PLoS ONE 11: e0159218.
- Thom, D., W. Rammer, T. Dirnböck, J. Müller, J. Kobler, K. Katzensteiner, N. Helm, and R. Seidl. 2017a. The impacts of climate change and disturbance on spatio-temporal trajectories of biodiversity in a temperate forest landscape. Journal of Applied Ecology 54: 28–38.
- Thom, D., W. Rammer, and R. Seidl. 2017b. Disturbances catalyze the adaptation of forest ecosystems to changing climate conditions. Global Change Biology 23: 269–282.
- Tinker, D. B., W. H. Romme, W. W. Hargrove, R. H. Gardner, and M. G. Turner. 1994. Landscape-scale heterogeneity in lodgepole pine serotiny. Canadian Journal of Forest Research 24: 897–903.
- Trumbore, S., P. Brando, and H. Hartmann. 2015. Forest health and global change. Science 349: 814–818.
- Turetsky, M. R., J. L. Baltzer, J. F. Johnstone, M. C. Mack, K. Mccann, and E. A. G. Schuur. 2016. Losing legacies, ecological release, and transient responses: key challenges for the future of northern ecosystem science. Ecosystems 20: 23–30.
- Turner, M. G. 2010. Disturbance and landscape dynamics in a changing world. Ecology 91: 2833–2849.
- Turner, M. G., W. W. Hargrove, R. H. Gardner, and W. H. Romme. 1994. Effects of fire on landscape heterogeneity in Yellowstone National Park, Wyoming. Journal of Vegetation Science 5: 731–742.
- Turner, M. G., W. H. Romme, R. H. Gardner, and W. W. Hargrove. 1997. Effects of fire size and pattern on early succession in Yellowstone National Park. Ecological Monographs 67: 411–433.
- Turner, M. G., W. L. Baker, C. J. Peterson, and R. K. Peet. 1998. Factors influencing succession: lessons from large, infrequent natural disturbances. Ecosystems 1: 511–523.
- Turner, M. G., W. H. Romme, and R. H. Gardner. 1999. Prefire heterogeneity, fire severity, and early postfire plant reestablishment in subalpine forests of Yellowstone National Park, WY. International Journal of Wildland Management 9: 21–36.
- Turner, M. G., D. Tinker, W. Romme, D. Kashian, and C. Litton. 2004. Landscape patterns of sapling density, leaf area, and aboveground net primary production in postfire lodgepole pine forests, Yellowstone National Park (USA). Ecosystems 7: 751–775.
- Turner, M. G., D. M. Turner, W. H. Romme, and D. B. Tinker. 2007. Cone production in young post-fire Pinus contorta stands in Greater Yellowstone (USA). Forest Ecology and Management 242: 119–126.
- Turner, M. G., D. C. Donato, and W. H. Romme. 2013. Consequences of spatial heterogeneity for ecosystem services in changing forest landscapes: priorities for future research. Landscape Ecology 28: 1081–1097.
- Turner, M. G., T. G. Whitby, D. B. Tinker, and W. H. Romme. 2016. Twenty-four years after the Yellowstone Fires: Are postfire lodgepole pine stands converging in structure and function? Ecology 97: 1260–1273.
- Voldoire, A., et al. 2013. The CNRM-CM5.1 global climate model: description and basic evaluation. Climate Dynamics 40: 2091–2121.
- Walck, J. L., S. N. Hidayati, K. W. Dixon, K. Thompson, and P. Poschlod. 2011. Climate change and plant regeneration from seed. Global Change Biology 17: 2145–2161.
- Walker, B., L. Gunderson, A. Zinzig, C. Folke, S. Carpenter, and L. Schultz. 2006. A handful of heuristics and some propositions for understanding resilience in social-ecological systems. Ecology and Society 11: 13.
- Walker, X. J., M. C. Mack, and J. F. Johnstone. 2016. Predicting ecosystem resilience to fire from tree ring analysis in black spruce forests. Ecosystems 20: 1137–1150.
- Westerling, A. L. 2016. Increasing western US forest wildfire activity: sensitivity to changes in the timing of spring. Philosophical Transactions of the Royal Society B 371: 1–10.
- Westerling, A. L., H. G. Hidalgo, D. R. Cayan, and T. W. Swetnam. 2006. Warming and earlier spring increase western US forest wildfire activity. Science 313: 940–943.
- Westerling, A. L., M. G. Turner, E. A. H. Smithwick, W. H. Romme, and M. G. Ryan. 2011. Continued warming could transform Greater Yellowstone fire regimes by mid-21st century. Proceedings of the National Academy of Sciences USA 108: 13165–13170.
- Western Regional Climate Center 2017a. NCDC 1981–2016 monthly normals, Old Faithful, WY. https://wrcc.dri.edu/cgi-bin/cliMAIN.pl?wy6845.
- Western Regional Climate Center 2017b. NCDC 1981–2016 monthly normals, Mammoth, WY. https://wrcc.dri.edu/cgi-bin/cliMAIN.pl?wy9905.
- Whitlock, C. 1993. Postglacial vegetation and climate of Grand Teton and southern Yellowstone National Parks. Ecological Monographs 63: 173–198.