Beverly, J. L., Herd, E. P., & Conner, J. R. (2009). Modeling fire susceptibility in west central Alberta, Canada. Forest Ecology and Management, 258(7), 1465-1478.

Bonnycastle, A., Yang, W., & Mersey, J. (2017). Introduction to Spatial Analyst in ArcGIS. Department of Geography, University of Guelph. Guelph, Ontario.

The Canadian Press. ( 2017, September 15). B.C. lifts state of emergency over wildfires but danger isn't over. CTV News, Retrieved from: https://www.ctvnews.ca/canada/b-c-lifts-state-of-emergency-over-wildfire...

Chuvieco, E., Martínez, S., Román, M. V., Hantson, S., & Pettinari, M. L. (2014). Integration of ecological and socio‐economic factors to assess global vulnerability to wildfire. Global Ecology and Biogeography, 23(2), 245-258.

Demarchi, D. A. (2011). The British Columbia Ecoregion Classification. Victoria, British Columbia, Canada: Ecosystem Information Section, Ministry of Environment.

Duff, T. J., Keane, R. E., Penman, T. D., & Tolhurst, K. G. (2017). Revisiting Wildland Fire Fuel Quantification Methods: The Challenge of Understanding a Dynamic, Biotic Entity. Forests, 8(9), 351.

Fischer, J.T. & Wilkinson, L. (2005). The response of mammals to forest fire and timber harvest in the North American boreal forest. Mammal Review, 35(1), 51-81.

Galiana-Martin, L. & Karlsson, O. (2012). Development of a Methodology for the Assessment of Vulnerability Related to Wildland Fires Using a Multi‐Criteria Evaluation. Geographical Research, 50(3), 304-319.

Gralewicz, N. J. (2010). Spatial and temporal patterns of wildfire occurrence and susceptibility in Canada (Doctoral dissertation)

Government of British Columbia. (2017). Current Wildfire Situation. Retrieved from: https://www2.gov.bc.ca/gov/content/safety/wildfire-status/wildfire-situa...

Keane, R. E., Agee, J. K., Fulé, P., Keeley, J. E., Key, C., Kitchen, S. G., Miller, R. & Schulte, L. A. (2009). Ecological effects of large fires on US landscapes: benefit or catastrophe? A. International Journal of Wildland Fire, 17(6), 696-712.

Kilinc, M., & Beringer, J. (2007). The spatial and temporal distribution of lightning strikes and their relationship with vegetation type, elevation, and fire scars in the Northern Territory. Journal of climate, 20(7), 1161-1173.

Kuester, M. A., Marshall, J., & Emery, W. J. (2005). Remote sensing and modeling of wildfires. Ball Aerospace and Technologies Corp Boulder Co.

Lawson, B. D., & Armitage, O. B. (2008). Weather guide for the Canadian forest fire danger rating system. Edmonton: Natural Resources Canada.

Martínez, J., Vega-Garcia, C., & Chuvieco, E. (2009). Human-caused wildfire risk rating for prevention planning in Spain. Journal of environmental management, 90(2), 1241-1252.

Mori, A. S., & Johnson, E. A. (2013). Assessing possible shifts in wildfire regimes under a changing climate in mountainous landscapes. Forest ecology and management, 310, 875-886.

NASA (2015) [Untitled image satellite image of British Columbia wildfire]. Retrieved March 15, 2018 from https://bc.ctvnews.ca/b-c-wildfire-smoke-visible-from-space-as-air-quali....

Natural Resources Canada. (2016). Social aspects of wildfire management. Retrieved from: http://www.nrcan.gc.ca/forests/fire-insects-disturbances/fire/14444

Nitschke, C. R., & Innes, J. L. (2008). Climatic change and fire potential in South‐Central British Columbia, Canada. Global Change Biology, 14(4), 841-855.

Parisien, M. A., Kafka, V. G., Hirsch, K. G., Todd, J. B., Lavoie, S. G., & Maczek, P. D. (2005). Mapping wildfire susceptibility with the BURN-P3 simulation model. Edmonton (AB): Natural Resources Canada, Canadian Forest Service, Northern Forestry Centre. p, 36.

Pettinari, M. L., & Chuvieco, E. (2017). Fire Behavior Simulation from Global Fuel and Climatic Information. Forests, 8(6), 179.

Platt, R. V. (2014). Wildfire hazard in the home ignition zone: an object-oriented analysis integrating LiDAR and VHR satellite imagery. Applied Geography, 51, 108-117.

Renkin, R. A., & Despain, D. G. (1992). Fuel moisture, forest type, and lightning-caused fire in Yellowstone National Park. Canadian Journal of Forest Research, 22(1), 37-45.

Semlitsch , R.D., Todd, B.D.,Blomquist, S.M., Calhoun, A.J., Gibbons, J.W., Gibbs, J.P, Graeter, G.J., Harper, E.B., Hocking, D.J., Hunter, M.L., Patrick, D.A., Rittenhouse, T.A., & Rothermel, B.B. (2009). Effects of Timber Harvest on Amphibian Populations: Understanding Mechanisms from Forest Experiments. Bioscience, 59(10), 853-862.

Stephens, S. L., Agee, J. K., Fulé, P. Z., North, M. P., Romme, W. H., Swetnam, T. W., & Turner, M. G. (2013). Managing forests and fire in changing climates. Science, 342(6154), 41-42.

Taylor, S. W., Woolford, D. G., Dean, C. B., & Martell, D. L. (2013). Wildfire prediction to inform management: statistical science challenges. Statistical Science, 586-615.

Thompson, M. P., Haas, J. R., Gilbertson-Day, J. W., Scott, J. H., Langowski, P., Bowne, E., & Calkin, D. E. (2015). Development and application of a geospatial wildfire exposure and risk calculation tool. Environmental Modelling & Software, 63, 61-72.

Thompson, D. K., Parisien, M. A., Morin, J., Millard, K., Larsen, C. P., & Simpson, B. N. (2017). Fuel accumulation in a high-frequency boreal wildfire regime: from wetland to upland. Canadian Journal of Forest Research, 47(7), 957-964.

Tittler, R., Messier, C., & Fall, A. (2012). Concentrating anthropogenic disturbance to balance ecological and economic values: applications to forest management. Ecological Applications, 22(4), 1268-1277.

Tutsch, M., Haider, W., Beardmore, B., Lertzman, K., Cooper, A. B., & Walker, R. C. (2010). Estimating the consequences of wildfire for wildfire risk assessment, a case study in the southern Gulf Islands, British Columbia, Canada. Canadian Journal of Forest Research, 40(11), 2104-2114.

[Untitled image of British Columbia wildfire] retrieved March 15, 2018 from http://bctvkootenays.com/2017/07/04/parts-of-southeast-bc-reach-extreme-...

Valdez, M. C., Chang, K. T., Chen, C. F., Chiang, S. H., & Santos, J. L. (2017). Modelling the spatial variability of wildfire susceptibility in Honduras using remote sensing and geographical information systems. Geomatics, Natural Hazards and Risk, 8(2), 876-892.

Woolford, D. G., Dean, C. B., Martell, D. L., Cao, J., & Wotton, B. M. (2014). Lightning‐caused forest fire risk in Northwestern Ontario, Canada, is increasing and associated with anomalies in fire weather. Environmetrics, 25(6), 406-416.

Zhang, Z., Zhang, H., & Zhou, D. (2010). Using GIS spatial analysis and logistic regression to predict the probabilities of human-caused grassland fires. Journal of Arid Environments, 74(3), 386-393.

Zhou, S., Chen, G., Fang, L. & Nie, Y. (2016). GID-Based Integration of Subjective and Objective weighting Methods for Regional Landslides Susceptibility Mapping. Sustainability.