Journal list menu
Article
Severe fire weather and intensive forest management increase fire severity in a multi-ownership landscape
Harold S. J. Zald,
Christopher J. Dunn,
Corresponding Author
Harold S. J. Zald
Department of Forestry and Wildland Resources, Humboldt State University, 1 Harpst Street, Arcata, California, 95521 USA
E-mail: [email protected]Search for more papers by this authorChristopher J. Dunn
Department of Forest Engineering, Resources, and Management, Oregon State University, 280 Peavy Hall, Corvallis, Oregon, 97331 USA
Search for more papers by this authorHarold S. J. Zald,
Christopher J. Dunn,
Corresponding Author
Harold S. J. Zald
Department of Forestry and Wildland Resources, Humboldt State University, 1 Harpst Street, Arcata, California, 95521 USA
E-mail: [email protected]Search for more papers by this authorChristopher J. Dunn
Department of Forest Engineering, Resources, and Management, Oregon State University, 280 Peavy Hall, Corvallis, Oregon, 97331 USA
Search for more papers by this authorCorresponding Editor: Bradford P. Wilcox.
Abstract
Many studies have examined how fuels, topography, climate, and fire weather influence fire severity. Less is known about how different forest management practices influence fire severity in multi-owner landscapes, despite costly and controversial suppression of wildfires that do not acknowledge ownership boundaries. In 2013, the Douglas Complex burned over 19,000 ha of Oregon & California Railroad (O&C) lands in Southwestern Oregon, USA. O&C lands are composed of a checkerboard of private industrial and federal forestland (Bureau of Land Management, BLM) with contrasting management objectives, providing a unique experimental landscape to understand how different management practices influence wildfire severity. Leveraging Landsat based estimates of fire severity (Relative differenced Normalized Burn Ratio, RdNBR) and geospatial data on fire progression, weather, topography, pre-fire forest conditions, and land ownership, we asked (1) what is the relative importance of different variables driving fire severity, and (2) is intensive plantation forestry associated with higher fire severity? Using Random Forest ensemble machine learning, we found daily fire weather was the most important predictor of fire severity, followed by stand age and ownership, followed by topographic features. Estimates of pre-fire forest biomass were not an important predictor of fire severity. Adjusting for all other predictor variables in a general least squares model incorporating spatial autocorrelation, mean predicted RdNBR was higher on private industrial forests (RdNBR 521.85 ± 18.67 [mean ± SE]) vs. BLM forests (398.87 ± 18.23) with a much greater proportion of older forests. Our findings suggest intensive plantation forestry characterized by young forests and spatially homogenized fuels, rather than pre-fire biomass, were significant drivers of wildfire severity. This has implications for perceptions of wildfire risk, shared fire management responsibilities, and developing fire resilience for multiple objectives in multi-owner landscapes.
Supporting Information
| Filename | Description |
|---|---|
| eap1710-sup-0001-AppendixS1.pdfPDF document, 1.2 MB |
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., C. A. Kolden, A. P. Williams, J. A. Lutz, and A. M. S. Smith. 2017. Climatic influences on interannual variability in regional burn severity across western US forests. International Journal of Wildland Fire 26: 269.
- Agee, J. K., and C. N. Skinner. 2005. Basic principles of forest fuel reduction treatments. Forest Ecology and Management 211: 83–96.
- Barros, A. M. G., et al. 2017. Spatiotemporal dynamics of simulated wildfire, forest management, and forest succession in central Oregon, USA. Ecology and Society 22: 24.
- Bell, D. M., M. J. Gregory, H. M. Roberts, R. J. David, and J. L. Ohmann. 2015. How sampling and scale limit accuracy assessment of vegetation maps: a comment on Loehle et al. (2015). Forest Ecology and Management 358: 361–364.
- Birch, D. S., P. Morgan, C. A. Kolden, J. T. Abatzoglou, G. K. Dillon, A. T. Hudak, and A. M. S. Smith. 2015. Vegetation, topography and daily weather influenced burn severity in central Idaho and western Montana forests. Ecosphere 6: art17.
- Bradley, C. M., C. T. Hanson, and D. A. DellaSala. 2016. Does increased forest protection correspond to higher fire severity in frequent-fire forests of the western United States? Ecosphere 7: e01492.
- Bradshaw, L., J. Deeming, R. Burgan, and J. Cohen. 1983. The 1978 national fire-danger rating system. General Technical Report INT-169. US Department of Agriculture, Forest Service, Intermountain Forest and Range Experiment Station, Ogden, Utah, USA.
- Bradshaw, L., and E. McCormick. 2000. FireFamily Plus user's guide, version 2.0. Gen. Tech. Rep. RMRS-GTR-67WWW. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Ogden, Utah, USA.
- Bradstock, R. A., K. A. Hammill, L. Collins, and O. Price. 2010. Effects of weather, fuel and terrain on fire severity in topographically diverse landscapes of south-eastern Australia. Landscape Ecology 25: 607–619.
- Burnham, K. P., and D. R. Anderson. 2002. Model selection and multi-model inference: a practical information-theoretic approach. Springer Verlag, New York, New York, USA.
- Calkin, D. E., M. P. Thompson, and M. A. Finney. 2015. Negative consequences of positive feedbacks in US wildfire management. Forest Ecosystems 2: 9.
- Campbell, J. L., M. E. Harmon, and S. R. Mitchell. 2012. Can fuel-reduction treatments really increase forest carbon storage in the western US by reducing future fire emissions? Frontiers in Ecology and the Environment 10: 83–90.
- Cansler, C. A., and D. McKenzie. 2014. Climate, fire size, and biophysical setting control fire severity and spatial pattern in the northern Cascade Range, USA. Ecological Applications 24: 1037–1056.
- Cohen, W. B., T. A. Spies, and M. Fiorella. 1995. Estimating the age and structure of forests in a multi-ownership landscape of western Oregon, USA. International journal of Remote Sensing 16: 721–746.
- Collins, B. M., J. M. Lydersen, R. G. Everett, D. L. Fry, and S. L. Stephens. 2015. Novel characterization of landscape-level variability in historical vegetation structure. Ecological Applications 25: 1167–1174.
- Collins, B. M., S. L. Stephens, J. J. Moghaddas, and J. J. Battles. 2010. Challenges and approaches in planning fuel treatments across fire-excluded forested landscapes. Journal of Forestry 108: 24–31.
- Crecente-Campo, F., A. Pommerening, and R. Rodríguez-Soalleiro. 2009. Impacts of thinning on structure, growth and risk of crown fire in a Pinus sylvestris L. plantation in northern Spain. Forest Ecology and Management 257: 1945–1954.
- Davis, R. J., et al. 2015. Northwest Forest Plan–the first 20 years (1994–2013): status and trends of late-successional and old-growth forests. U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, Portland, Oregon, USA.
- Del Lungo, L., P. Vourinen, and J. Carle. 2001. Preliminary analysis of global trends in forest plantation development, 1980–2000. FAO, Rome, Italy.
- Dillon, G. K., Z. A. Holden, P. Morgan, M. A. Crimmins, E. K. Heyerdahl, and C. H. Luce. 2011. Both topography and climate affected forest and woodland burn severity in two regions of the western US, 1984 to 2006. Ecosphere 2: art130.
- Donato, D. C., J. L. Campbell, and J. F. Franklin. 2011. Multiple successional pathways and precocity in forest development: Can some forests be born complex? Journal of Vegetation Science 23: 576–584.
- Dormann, C., et al. 2007. Methods to account for spatial autocorrelation in the analysis of species distributional data: a review. Ecography 30: 609–628.
- Dunn, C. J., and J. D. Bailey. 2016. Tree mortality and structural change following mixed-severity fire in Pseudotsuga forests of Oregon's western Cascades, USA. Forest Ecology and Management 365: 107–118.
- Dunn, C. J., D. E. Calkin, and M. P. Thompson. 2017. Towards enhanced risk management: planning, decision making and monitoring of US wildfire response. International Journal of Wildland Fire 26: 551–556.
- Earles, J. M., M. P. North, and M. D. Hurteau. 2014. Wildfire and drought dynamics destabilize carbon stores of fire-suppressed forests. Ecological Applications 24: 732–740.
- Estes, B. L., E. E. Knapp, C. N. Skinner, J. D. Miller, and H. K. Preisler. 2017. Factors influencing fire severity under moderate burning conditions in the Klamath Mountains, northern California, USA. Ecosphere 8: e01794.
- Finney, M. A., R. C. Seli, C. W. McHugh, A. A. Ager, B. Bahro, and J. K. Agee. 2007. Simulation of long-term landscape-level fuel treatment effects on large wildfires. International Journal of Wildland Fire 16: 712.
- Fischer, A. P., et al. 2016. Wildfire risk as a socioecological pathology. Frontiers in Ecology and the Environment 14: 276–284.
- Flannigan, M. D., J. B. Harrington, M. D. Flannigan, and J. B. Harrington. 1988. A study of the relation of meteorological variables to monthly provincial area burned by wildfire in Canada (1953–80). Journal of Applied Meteorology 27: 441–452.
- Food and Agriculture Organization of the United Nations [FAO]. 2010. Global forest resource assessment. FAO, Rome, Italy.
- Franklin, J. F., and C. T. Dyrness. 1988. Natural vegetation of Oregon and Washington. Oregon State University Press, Corvallis, Oregon, USA.
- Franklin, J. F., and K. N. Johnson. 2012. A restoration framework for federal forests in the pacific northwest. Journal of Forestry 110: 429–439.
- Franklin, J. F., T. A. Spies, R. Van Pelt, A. B. Carey, D. A. Thornburgh, D. R. Berg, D. B. Lindenmayer, M. E. Harmon, W. S. Keeton, and D. C. Shaw. 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.
- Fulé, P. Z., J. E. Korb, and R. Wu. 2009. Changes in forest structure of a mixed conifer forest, southwestern Colorado, USA. Forest Ecology and Management 258: 1200–1210.
- Genuer, R., J.-M. Poggi, and C. Tuleau-Malot. 2010. Variable selection using random forests. Pattern Recognition Letters 31: 2225–2236.
- Genuer, R., J.-M. Poggi, and C. Tuleau-Malot. 2016. VSURF: variable selection using random forests. R package version 1.0.3. https://cran.r-project.org/web/packages/VSURF/index.html
- Geospatial Multi-Agency Coordination (GeoMAC). 2013. Douglas complex fire perimeters. https://rmgsc.cr.usgs.gov/outgoing/GeoMAC/2013_fire_data/Oregon/Douglas_Complex/
- Gesch, D. B., M. J. Oimoen, S. K. Greenlee, C. A. Nelson, M. J. Steuck, and D. J. Tyler. 2002. The national elevation data set. Photogrammetric Engineering and Remote Sensing 68: 5–11.
- Haas, J. R., D. E. Calkin, and M. P. Thompson. 2013. A national approach for integrating wildfire simulation modeling into Wildland Urban Interface risk assessments within the United States. Landscape and Urban Planning 119: 44–53.
- Hanson, C. T., D. C. Odion, D. A. DelleaSala, and W. L. Baker. 2009. Overestimation of fire risk in the Northern Spotted Owl recovery plan. Conservation Biology 23: 1314–1319.
- Harvey, B. J., D. C. Donato, and M. G. Turner. 2016. Drivers and trends in landscape patterns of stand-replacing fire in forests of the US Northern Rocky Mountains (1984–2010). Landscape Ecology 31: 2367–2383.
- Hastie, T., R. Tibshirani, J. Friedman, and J. Franklin. 2001. The elements of statistical learning: data mining, inference, and prediction. Springer, New York, New York, USA.
10.1007/978-0-387-21606-5 Google Scholar
- Hessburg, P. F., J. K. Agee, and J. F. Franklin. 2005. Dry forests and wildland fires of the inland Northwest USA: contrasting the landscape ecology of the pre-settlement and modern eras. Forest Ecology and Management 211: 117–139.
- Hirsch, K., V. Kafka, C. Tymstra, R. McAlpine, B. Hawkes, H. Stegehuis, S. Quintilio, S. Gauthier, and K. Peck. 2001. Fire-smart forest management: a pragmatic approach to sustainable forest management in fire-dominated ecosystems. Forestry Chronicle 77: 357–363.
- Hurteau, M. D., G. W. Koch, and B. A. Hungate. 2008. Carbon protection and fire risk reduction: toward a full accounting of forest carbon offsets. Frontiers in Ecology and the Environment 6: 493–498.
- Jolly, W. M., M. A. Cochrane, P. H. Freeborn, Z. A. Holden, T. J. Brown, G. J. Williamson, and D. M. Bowman. 2015. Climate-induced variations in global wildfire danger from 1979 to 2013. Nature Communications 6: 7537.
- Kane, V. R., C. A. Cansler, N. A. Povak, J. T. Kane, R. J. McGaughey, J. A. Lutz, D. J. Churchill, and M. P. North. 2015. Mixed severity fire effects within the Rim fire: relative importance of local climate, fire weather, topography, and forest structure. Forest Ecology and Management 358: 62–79.
- Keane, R. E., R. Burgan, and J. van Wagtendonk. 2001. Mapping wildland fuels for fire management across multiple scales: integrating remote sensing, GIS, and biophysical modeling. International Journal of Wildland Fire 10: 301–319.
- Kennedy, R. E., Z. Yang, and W. B. Cohen. 2010. Detecting trends in forest disturbance and recovery using yearly Landsat time series: 1. LandTrendr—temporal segmentation algorithms. Remote Sensing of Environment 114: 2897–2910.
- Kobziar, L. N., J. R. McBride, and S. L. Stephens. 2009. The efficacy of fire and fuels reduction treatments in a Sierra Nevada pine plantation. International Journal of Wildland Fire 18: 791.
- Krofcheck, D. J., M. D. Hurteau, R. M. Scheller, and E. L. Loudermilk. 2017. Prioritizing forest fuels treatments based on the probability if high-severity fire restores adaptive capacity in Sierran forests. Global Change Biology. https://doi.org/10.1111/gcb.13913
- Landram, M. 1996. Status of reforestation on National Forest lands within the Sierra Nevada Ecosystem Project Study Area. Page Sierra Nevada Ecosystem Project: Final Report to Congress (Volume 3). University of California, Centers for Water and Wildland Resources, Davis, CA USA.
- Liaw, A., and M. Wiener. 2002. Classification and regression by randomForest. R News 2: 18–22.
- Littell, J. S., D. McKenzie, D. L. Peterson, and A. L. Westerling. 2009. Climate and wildfire area burned in western US ecoprovinces, 1916–2003. Ecological Applications 19: 1003–1021.
- Lu, D. 2006. The potential and challenge of remote sensing-based biomass estimation. International Journal of Remote Sensing 27: 1297–1328.
- Lyons-Tinsley, C., and D. L. Peterson. 2012. Surface fuel treatments in young, regenerating stands affect wildfire severity in a mixed conifer forest, eastside Cascade Range, Washington, USA. Forest Ecology and Management 270: 117–125.
- Mazerolle, M. J. 2017. AICcmodavg: model selection and multimodel inference based on (Q) AIC (c). R package version, 2.1. https://cran.r-project.org/web/packages/AICcmodavg/index.html
- McCaffrey, S. 2004. Thinking of wildfire as a natural hazard. Society and Natural Resources 17: 509–516.
- McCune, B., and D. Keon. 2002. Equations for potential annual direct incident radiation and heat load. Journal of Vegetation Science 13: 603.
- Meigs, G. W., H. S. Zald, J. L. Campbell, W. S. Keeton, and R. E. Kennedy. 2016. Do insect outbreaks reduce the severity of subsequent forest fires? Environmental Research Letters 11: 045008.
- Merschel, A. G., T. A. Spies, and E. K. Heyerdahl. 2014. Mixed-conifer forests of central Oregon: effects of logging and fire exclusion vary with environment. Ecological Applications 24: 1670–1688.
- Miller, J. D., H. D. Safford, M. Crimmins, and A. E. Thode. 2009. Quantitative evidence for increasing forest fire severity in the Sierra Nevada and southern Cascade Mountains, California and Nevada, USA. Ecosystems 12: 16–32.
- Miller, J. D., C. N. Skinner, H. D. Safford, E. E. Knapp, and C. M. Ramirez. 2012. Trends and causes of severity, size, and number of fires in northwestern California, USA. Ecological Applications 22: 184–203.
- Miller, J. D., and A. E. Thode. 2007. Quantifying burn severity in a heterogeneous landscape with a relative version of the delta normalized burn ratio (dNBR). Remote Sensing of Environment 109: 66–80.
- Naficy, C., A. Sala, E. G. Keeling, J. Graham, and T. H. DeLuca. 2010. Interactive effects of historical logging and fire exclusion on ponderosa pine forest structure in the northern Rockies. Ecological Applications 20: 1851–1864.
- Nahuelhual, L., A. Carmona, A. Lara, C. Echeverría, and M. E. González. 2012. Land-cover change to forest plantations: proximate causes and implications for the landscape in south-central Chile. Landscape and Urban Planning 107: 12–20.
- North, M. P., S. L. Stephens, B. M. Collins, J. K. Agee, G. Aplet, J. F. Franklin, and P. Z. Fulé. 2015a. Reform forest fire management. Science 349: 1280–1281.
- North, M., A. Brough, J. Long, B. Collins, P. Bowden, D. Yasuda, J. Miller, and N. Sugihara. 2015b. Constraints on mechanized treatment significantly limit mechanical fuels reduction extent in the Sierra Nevada. Journal of Forestry 113: 40–48.
- Odion, D. C., E. J. Frost, J. R. Strittholt, H. Jiang, D. A. DellaSala, and M. A. Moritz. 2004. Patterns of fire severity and forest conditions in the western Klamath Mountains, California. Conservation Biology 18: 927–936.
- Odion, D. C., et al. 2014. Examining historical and current mixed-severity fire regimes in Ponderosa pine and mixed-conifer forests of western North America. PLoS ONE 9: e87852.
- Ohmann, J. L., and M. J. Gregory. 2002. Predictive mapping of forest composition and structure with direct gradient analysis and nearest-neighbor imputation in coastal Oregon, USA. Canadian Journal of Forest Research 32: 725–741.
- Ohmann, J. L., M. J. Gregory, and H. M. Roberts. 2014. Scale considerations for integrating forest inventory plot data and satellite image data for regional forest mapping. Remote Sensing of Environment 151: 3–15.
- Ohmann, J. L., M. J. Gregory, H. M. Roberts, W. B. Cohen, R. E. Kennedy, and Z. Yang. 2012. Mapping change of older forest with nearest-neighbor imputation and Landsat time-series. Forest Ecology and Management 272: 13–25.
- Oregon Spatial Data Library. 2015. Oregon land management—2015. http://spatialdata.oregonexplorer.info/geoportal/catalog/search/resource/details.page?uuid=%7B9B644E0F-7A7D-4124-A50F-6B35C05626AE%7D
- Parsons, R., R. Linn, F. Pimont, C. Hoffman, J. Sauer, J. Winterkamp, C. Sieg, and W. Jolly. 2017. Numerical investigation of aggregated fuel spatial pattern impacts on fire behavior. Land 6: 43.
- Pierce, K. B., J. L. Ohmann, M. C. Wimberly, M. J. Gregory, and J. S. Fried. 2009. Mapping wildland fuels and forest structure for land management: a comparison of nearest neighbor imputation and other methods. Canadian Journal of Forest Research 39: 1901–1916.
- Pimont, F., J.-L. Dupuy, R. R. Linn, and S. Dupont. 2011. Impacts of tree canopy structure on wind flows and fire propagation simulated with FIRETEC. Annals of Forest Science 68: 523–530.
- Pinheiro, J., D. Bates, S. DebRoy, D. Sarkar, and R. C. Team. 2017. nlme: linear and nonlinear mixed effects models. https://cran.r-project.org/web/packages/nlme/index.html
- Prichard, S. J., and M. C. Kennedy. 2014. Fuel treatments and landform modify landscape patterns of burn severity in an extreme fire event. Ecological Applications 24: 571–590.
- R Core Team. 2017. R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria.
- Raymond, C. L., and D. L. Peterson. 2005. Fuel treatments alter the effects of wildfire in a mixed-evergreen forest, Oregon, USA. Canadian Journal of Forest Research 35: 2981–2995.
- Reilly, M. J., C. J. Dunn, G. W. Meigs, T. A. Spies, R. E. Kennedy, J. D. Bailey, and K. Briggs. 2017. Contemporary patterns of fire extent and severity in forests of the Pacific Northwest, USA (1985–2010). Ecosphere 8: e01695.
- Reiner, A. L., N. M. Vaillant, J. Fites-Kaufman, and S. N. Dailey. 2009. Mastication and prescribed fire impacts on fuels in a 25-year old ponderosa pine plantation, southern Sierra Nevada. Forest Ecology and Management 258: 2365–2372.
- Rodríguez y Silva, F., J. R. Molina Martínez, and A. González-Cabán. 2014. A methodology for determining operational priorities for prevention and suppression of wildland fires. International Journal of Wildland Fire 23: 544.
- Rothermel, R. 1972. A mathematical model for predicting fire spread in wildland fuels. Page 40. Research Paper INT-115, USDA Forest Service, Intermountain Forest and Range Experiment Station, Ogden, Utah USA.
- Rudel, T. K. 2009. Tree farms: driving forces and regional patterns in the global expansion of forest plantations. Land Use Policy 26: 545–550.
- Ryan, K. C., and E. D. Reinhardt. 1988. Predicting postfire mortality of seven western conifers. Canadian Journal of Forest Research 18: 1291–1297.
- Safford, H. D., D. A. Schmidt, and C. H. Carlson. 2009. Effects of fuel treatments on fire severity in an area of wildland–urban interface, Angora Fire, Lake Tahoe Basin, California. Forest Ecology and Management 258: 773–787.
- Schoennagel, T., et al. 2017. Adapt to more wildfire in western North American forests as climate changes. Proceedings of the National Academy of Sciences USA 114: 4582–4590.
- 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.
- Sensenig, T., J. D. Bailey, and J. C. Tappeiner. 2013. Stand development, fire and growth of old-growth and young forests in southwestern Oregon, USA. Forest Ecology and Management 291: 96–109.
- Spies, T. A., K. N. Johnson, K. M. Burnett, J. L. Ohmann, B. C. McComb, G. H. Reeves, P. Bettinger, J. D. Kline, and B. Garber-Yonts. 2007. Cumulative ecological and socioeconomic effects of forest policies in coastal Oregon. Ecological Applications 17: 5–17.
- Spies, T. A., et al. 2010. Underestimating risks to the Northern Spotted Owl in fire-prone forests: response to Hanson et al. Conservation Biology 24: 330–333.
- Spies, T., et al. 2014. Examining fire-prone forest landscapes as coupled human and natural systems. Ecology and Society 19: 9. http://dx.doi.org/10.5751/ES-06584-190309
- Steel, Z. L., H. D. Safford, and J. H. Viers. 2015. The fire frequency-severity relationship and the legacy of fire suppression in California forests. Ecosphere 6: 1–23.
- Stephens, S., R. Boerner, C. Fettig, J. Fontaine, B. Hartsough, P. Kennedy, and D. Schwilk. 2012. The effects of forest fuel-reduction treatments in the United States. BioScience 62: 549–560.
- Stephens, S. L., et al. 2014. Temperate and boreal forest mega-fires: characteristics and challenges. Frontiers in Ecology and the Environment 12: 115–122.
- Stevens, J. T., et al. 2016. Average stand age from forest inventory plots does not describe historical fire regimes in Ponderosa pine and mixed-conifer forests of western North America. PLoS ONE 11: e0147688.
- Talbert, C., and D. Marshall. 2005. Plantation productivity in the Douglas-fir region under intensive silvicultural practices: results from research and operations. Journal of Forestry 103: 65–70.
- Thompson, J. R., M. D. Anderson, and K. N. Johnson. 2004. Ecosystem management across ownerships: the potential for collision with antitrust laws. Conservation Biology 18: 1475–1481.
- Thompson, J. R., K. N. Johnson, M. Lennette, T. A. Spies, and P. Bettinger. 2006. Historical disturbance regimes as a reference for forest policy in a multiowner province: a simulation experiment. Canadian Journal of Forest Research 36: 401–417.
- Thompson, J. R., and T. A. Spies. 2010. Factors associated with crown damage following recurring mixed-severity wildfires and post-fire management in southwestern Oregon. Landscape Ecology 25: 775–789.
- Thompson, J. R., T. A. Spies, and L. M. Ganio. 2007. Reburn severity in managed and unmanaged vegetation in a large wildfire. Proceedings of the National Academy of Sciences USA 104: 10743–10748.
- Turner, D. P., W. B. Cohen, R. E. Kennedy, K. S. Fassnacht, and J. M. Briggs. 1999. Relationships between leaf area index and Landsat TM spectral vegetation indices across three temperate zone sites. Remote Sensing of Environment 70: 52–68.
- Weatherspoon, C. P., and C. N. Skinner. 1995. An assessment of factors associated with damage to tree crowns from the 1987 wildfires in northern California. Forest Science 41: 430–451.
- Weaver, H. 1943. Fire as an ecological and silvicultural factor in the Ponderosa-pine region of the pacific Slope. Journal of Forestry 41: 7–15.
- Westerling, A., and B. Bryant. 2008. Climate change and wildfire in California. Climatic Change 87: 231–249.
- Williams, J. 2013. Exploring the onset of high-impact mega-fires through a forest land management prism. Forest Ecology and Management 294: 4–10.
- Zald, H. S. J., J. L. Ohmann, H. M. Roberts, M. J. Gregory, E. B. Henderson, R. J. McGaughey, and J. Braaten. 2014. Influence of lidar, Landsat imagery, disturbance history, plot location accuracy, and plot size on accuracy of imputation maps of forest composition and structure. Remote Sensing of Environment 143: 26–38.
- Ziegler, J. P., C. Hoffman, M. Battaglia, and W. Mell. 2017. Spatially explicit measurements of forest structure and fire behavior following restoration treatments in dry forests. Forest Ecology and Management 386: 1–12.
