In-Situ and Remote Sensing Platforms for Mapping Fine-Fuels and Fuel-Types in Sonoran Semi-Desert Grasslands

Fire has historically played an important role in shaping the structure and composition of Sonoran semi-desert grassland vegetation. Yet, human use and land management activities have significantly altered arid grassland ecosystems over the last century, often producing novel fuel conditions. The variety of continuously updated satellite remote sensing systems provide opportunities for efficiently mapping combustible fine-fuels and fuel-types (e.g., grass, shrub, or tree cover) over large landscapes that are helpful for evaluating fire hazard and risk. For this study, we compared field ceptometer leaf area index (LAI) measurements to conventional means for estimating fine-fuel biomass on 20, 50 m × 20 m plots and 431, 0.5 m × 0.5 m quadrats on the Buenos Aires National Wildlife Refuge (BANWR) in southern Arizona. LAI explained 65% of the variance in fine-fuel biomass using simple linear regression. An additional 19% of variance was explained from Random Forest regression tree models that included herbaceous plant height and cover as predictors. Field biomass and vegetation measurements were used to map fine-fuel and vegetation cover (fuel-type) from plots on BANWR comparing outcomes from multi-date (peak green and dormant period) Worldview-3 (WV3) and Landsat Operational Land Imager (OLI) imagery. Fine-fuel biomass predicted from WV3 imagery combined with terrain information from a digital elevation model explained greater variance using regression tree models (65%) as compared to OLI models (58%). Vegetation indices developed using red-edge bands as well as modeled bare ground and herbaceous cover were important to improve WV3 biomass estimates. Land cover classification for 11 cover categories with high spatial resolution WV3 imagery showed 80% overall accuracy and highlighted areas dominated by non-native grasses with 87% user’s class accuracy. Mixed native and non-native grass and shrublands showed 59% accuracy and less common areas dominated by native grasses on plots showed low class accuracy (23%). Digital data layers from WV3 models showed a significantly positive relationship (r2 = 0.68, F = 119.2, p < 0.001) between non-native grass cover (e.g., Eragrostis lehmanniana) and average fine-fuel biomass within refuge fire management units. Overall, both WV3 and OLI produced similar fine-fuel biomass estimates although WV3 showed better model performance and helped characterized fine-scale changes in fuel-type and continuity across the study area.

[1]  R. Rothermel A Mathematical Model for Predicting Fire Spread in Wildland Fuels , 2017 .

[2]  Ruben Van De Kerchove,et al.  Monitoring grass nutrients and biomass as indicators of rangeland quality and quantity using random forest modelling and WorldView-2 data , 2015, Int. J. Appl. Earth Obs. Geoinformation.

[3]  G. Birth,et al.  Measuring the Color of Growing Turf with a Reflectance Spectrophotometer1 , 1968 .

[4]  M. Rollins LANDFIRE: a nationally consistent vegetation, wildland fire, and fuel assessment , 2009 .

[5]  A. Huete A soil-adjusted vegetation index (SAVI) , 1988 .

[6]  Matthew R. Levi,et al.  Biophysical influences on the spatial distribution of fire in the desert grassland region of the southwestern USA , 2016, Landscape Ecology.

[7]  P. Clifford,et al.  Modifying the t test for assessing the correlation between two spatial processes , 1993 .

[8]  Hui Qing Liu,et al.  An error and sensitivity analysis of the atmospheric- and soil-correcting variants of the NDVI for the MODIS-EOS , 1994, IEEE Trans. Geosci. Remote. Sens..

[9]  D. Schimel,et al.  Mechanisms of shrubland expansion: land use, climate or CO2? , 1995 .

[10]  Cho-ying Huang,et al.  Climate anomalies provide opportunities for large‐scale mapping of non‐native plant abundance in desert grasslands , 2008 .

[11]  C. Bahre Wildfire in Southeastern Arizona Between 1859 and 1890 , 1985 .

[12]  Luke J. Zachmann,et al.  WorldView-2 high spatial resolution improves desert invasive plant detection. , 2014 .

[13]  Andrea S. Laliberte,et al.  Mesquite recruitment in the Chihuahuan Desert: historic and prehistoric patterns with long-term impacts , 2006 .

[14]  T. Swetnam,et al.  Warming and Earlier Spring Increase Western U.S. Forest Wildfire Activity , 2006, Science.

[15]  J. Keeley,et al.  Fire Management Impacts on Invasive Plants in the Western United States , 2006, Conservation biology : the journal of the Society for Conservation Biology.

[16]  Max Kuhn,et al.  caret: Classification and Regression Training , 2015 .

[17]  M. McClaran,et al.  Spread of introduced Lehmann lovegrass Eragrostis lehmanniana Nees. in Southern Arizona, USA , 1992 .

[18]  S. Cridland,et al.  Application of NDVI for predicting fuel curing at landscape scales in northern Australia: can remotely sensed data help schedule fire management operations? , 2003 .

[19]  Mark Fischetti,et al.  Predicting wildfires. , 2007, Scientific American.

[20]  Samantha A. Setterfield,et al.  Adding Fuel to the Fire: The Impacts of Non-Native Grass Invasion on Fire Management at a Regional Scale , 2013, PloS one.

[21]  M. Finney FARSITE : Fire Area Simulator : model development and evaluation , 1998 .

[22]  Farid Melgani,et al.  Toward an Optimal SVM Classification System for Hyperspectral Remote Sensing Images , 2006, IEEE Transactions on Geoscience and Remote Sensing.

[23]  D. Sims,et al.  Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages , 2002 .

[24]  T. Devender,et al.  Exotic Plants in the Sonoran Desert Region, Arizona and Sonora , 1997 .

[25]  Josep Peñuelas,et al.  Photochemical reflectance index (PRI) and remote sensing of plant CO₂ uptake. , 2011, The New phytologist.

[26]  Steven I. Higgins,et al.  Physically motivated empirical models for the spread and intensity of grass fires , 2008 .

[27]  B. Gao NDWI—A normalized difference water index for remote sensing of vegetation liquid water from space , 1996 .

[28]  Laura M. Norman,et al.  Multi-index time series monitoring of drought and fire effects on desert grasslands , 2016 .

[29]  Russell G. Congalton,et al.  Assessing the accuracy of remotely sensed data : principles and practices , 1998 .

[30]  Dirac Twidwell,et al.  Nondestructive Estimation of Standing Crop and Fuel Moisture Content in Tallgrass Prairie☆ , 2018, Rangeland Ecology and Management.

[31]  J. A. Schell,et al.  Monitoring vegetation systems in the great plains with ERTS , 1973 .

[32]  S. C. Martin Ecology and management of southwestern semidesert grass-shrub ranges: the status of our knowledge. , 1975 .

[33]  M. Finney An Overview of FlamMap Fire Modeling Capabilities , 2006 .

[34]  David G. Williams,et al.  Response of net ecosystem gas exchange to a simulated precipitation pulse in a semi-arid grassland: the role of native versus non-native grasses and soil texture , 2004, Oecologia.

[35]  Mark E. Miller,et al.  Mexican Grasslands and the Changing Aridlands of Mexico: An Overview and a Case Study in Northwestern Mexico , 2012 .

[36]  J. Qi,et al.  Remote Sensing for Grassland Management in the Arid Southwest , 2006 .

[37]  Ronald J. Birk,et al.  Government programs for research and operational uses of commercial remote sensing data , 2003 .

[38]  A. Skidmore,et al.  Narrow band vegetation indices overcome the saturation problem in biomass estimation , 2004 .

[39]  Stephan J. Maas,et al.  Combining remote sensing and modeling for estimating surface evaporation and biomass production , 1995 .

[40]  Gary A. Peterson,et al.  Soil Attribute Prediction Using Terrain Analysis , 1993 .

[41]  M. Brooks,et al.  Resistance to Invasion and Resilience to Fire in Desert Shrublands of North America , 2011 .

[42]  R. M. Hoffer,et al.  Biomass estimation on grazed and ungrazed rangelands using spectral indices , 1998 .

[43]  S. Archer,et al.  Climate Change and Ecosystems of the Southwestern United States , 2008 .

[44]  Isabel Cristina Pascual Castaño,et al.  Fire models and methods to map fuel types: The role of remote sensing. , 2008 .

[45]  D. Richardson,et al.  Effects of Invasive Alien Plants on Fire Regimes , 2004 .

[46]  Osvaldo E. Sala,et al.  Inter-annual variation in primary production of a semi-arid grassland related to previous-year production , 2001 .

[47]  M. Robles,et al.  Enduring a decade of drought: Patterns and drivers of vegetation change in a semi-arid grassland , 2017 .

[48]  Grant J. Williamson,et al.  Climate-induced variations in global wildfire danger from 1979 to 2013 , 2015, Nature Communications.

[49]  John A. Richards,et al.  Remote Sensing Digital Image Analysis: An Introduction , 1999 .

[50]  J. Michaelsen,et al.  Estimating grassland biomass and leaf area index using ground and satellite data , 1994 .

[51]  A. Gitelson,et al.  Use of a green channel in remote sensing of global vegetation from EOS- MODIS , 1996 .

[52]  R. Keane,et al.  Mapping wildland fuels for fire management across multiple scales: Integrating remote sensing, GIS, and biophysical modeling , 2001 .

[53]  Huadong Guo,et al.  Evaluation of Three MODIS-Derived Vegetation Index Time Series for Dryland Vegetation Dynamics Monitoring , 2015, Remote. Sens..

[54]  J. Balch,et al.  Introduced annual grass increases regional fire activity across the arid western USA (1980–2009) , 2013, Global change biology.

[55]  Nicole M. Vaillant,et al.  Integrating Fire Behavior Models and Geospatial Analysis for Wildland Fire Risk Assessment and Fuel Management Planning , 2011 .

[56]  Sandra Eckert,et al.  Improved Forest Biomass and Carbon Estimations Using Texture Measures from WorldView-2 Satellite Data , 2012, Remote. Sens..

[57]  D. R. Cutler,et al.  Utah State University From the SelectedWorks of , 2017 .

[58]  Luke J. Zachmann,et al.  Modelling and mapping dynamic variability in large fire probability in the lower Sonoran Desert of south-western Arizona , 2014 .

[59]  P. Vitousek,et al.  Biological invasions by exotic grasses, the grass/fire cycle, and global change , 1992 .

[60]  J. Grace,et al.  Evaluation of non-destructive methods for estimating biomass in marshes of the upper Texas, USA coast , 2006, Wetlands.

[61]  A. Huete,et al.  Overview of the radiometric and biophysical performance of the MODIS vegetation indices , 2002 .

[62]  G. McPherson,et al.  Response of semi‐desert grasslands invaded by non‐native grasses to altered disturbance regimes , 2005 .

[63]  N. Sayre A History of Working Landscapes: The Altar Valley, Arizona, USA , 2007 .

[64]  Jake F. Weltzin,et al.  Leaf gas exchange and water status responses of a native and non-native grass to precipitation across contrasting soil surfaces in the Sonoran Desert , 2007, Oecologia.

[65]  Robert J. Hijmans,et al.  Geographic Data Analysis and Modeling , 2015 .

[66]  C. Bahre,et al.  Historic vegetation change, mesquite increases, and climate in southeastern Arizona , 1993 .

[67]  A. Rogers,et al.  Reducing signature variability in unmixing coastal marsh Thematic Mapper scenes using spectral indices , 2004 .

[68]  Maggi Kelly,et al.  Predicting Surface Fuel Models and Fuel Metrics Using Lidar and CIR Imagery in a Dense, Mountainous Forest , 2013 .

[69]  Mariana Belgiu,et al.  Quantitative evaluation of variations in rule-based classifications of land cover in urban neighbourhoods using WorldView-2 imagery , 2014, ISPRS journal of photogrammetry and remote sensing : official publication of the International Society for Photogrammetry and Remote Sensing.

[70]  J. Briggs,et al.  Woody vegetation expansion in a desert grassland: Prehistoric human impact? , 2007 .

[71]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[72]  N. Breda Ground-based measurements of leaf area index: a review of methods, instruments and current controversies. , 2003, Journal of experimental botany.

[73]  Onisimo Mutanga,et al.  High density biomass estimation for wetland vegetation using WorldView-2 imagery and random forest regression algorithm , 2012, Int. J. Appl. Earth Obs. Geoinformation.