Landscape Effects of Wildfire on Permafrost Distribution in Interior Alaska Derived from Remote Sensing

Climate change coupled with an intensifying wildfire regime is becoming an important driver of permafrost loss and ecosystem change in the northern boreal forest. There is a growing need to understand the effects of fire on the spatial distribution of permafrost and its associated ecological consequences. We focus on the effects of fire a decade after disturbance in a rocky upland landscape in the interior Alaskan boreal forest. Our main objectives were to (1) map near-surface permafrost distribution and drainage classes and (2) analyze the controls over landscape-scale patterns of post-fire permafrost degradation. Relationships among remote sensing variables and field-based data on soil properties (temperature, moisture, organic layer thickness) and vegetation (plant community composition) were analyzed using correlation, regression, and ordination analyses. The remote sensing data we considered included spectral indices from optical datasets (Landsat 7 Enhanced Thematic Mapper Plus (ETM+) and Landsat 8 Operational Land Imager (OLI)), the principal components of a time series of radar backscatter (Advanced Land Observing Satellite—Phased Array type L-band Synthetic Aperture Radar (ALOS-PALSAR)), and topographic variables from a Light Detection and Ranging (LiDAR)-derived digital elevation model (DEM). We found strong empirical relationships between the normalized difference infrared index (NDII) and post-fire vegetation, soil moisture, and soil temperature, enabling us to indirectly map permafrost status and drainage class using regression-based models. The thickness of the insulating surface organic layer after fire, a measure of burn severity, was an important control over the extent of permafrost degradation. According to our classifications, 90% of the area considered to have experienced high severity burn (using the difference normalized burn ratio (dNBR)) lacked permafrost after fire. Permafrost thaw, in turn, likely increased drainage and resulted in drier surface soils. Burn severity also influenced plant community composition, which was tightly linked to soil temperature and moisture. Overall, interactions between burn severity, topography, and vegetation appear to control the distribution of near-surface permafrost and associated drainage conditions after disturbance.

[1]  Joshua C. Koch,et al.  Runoff sources and flow paths in a partially burned, upland boreal catchment underlain by permafrost , 2014 .

[2]  Eric S. Kasischke,et al.  Modeling the effects of fire severity and climate warming on active layer thickness and soil carbon storage of black spruce forests across the landscape in interior Alaska , 2013 .

[3]  Vladimir E. Romanovsky,et al.  Evidence for warming and thawing of discontinuous permafrost in Alaska , 1999 .

[4]  T. Péwé,et al.  Quaternary geology of Alaska , 1975 .

[5]  Guido Grosse,et al.  Vulnerability of high‐latitude soil organic carbon in North America to disturbance , 2011 .

[6]  Kristofer D. Johnson,et al.  Distribution of near-surface permafrost in Alaska: Estimates of present and future conditions , 2015 .

[7]  Chien-Lu Ping,et al.  Soil catena sequences and fire ecology in the boreal forest of Alaska , 2005 .

[8]  Kenneth M. Hinkel,et al.  Estimating active-layer thickness over a large region: Kuparuk River Basin, Alaska, U.S.A , 1997 .

[9]  Bernd Etzelmüller,et al.  A ground temperature map of the North Atlantic permafrost region based on remote sensing and reanalysis data , 2015 .

[10]  M. Torre Jorgenson,et al.  Edaphic and microclimatic controls over permafrost response to fire in interior Alaska , 2013 .

[11]  F. Baret,et al.  Relating soil surface moisture to reflectance , 2002 .

[12]  G. Jenks The Data Model Concept in Statistical Mapping , 1967 .

[13]  A. McGuire,et al.  Topographic influences on wildfire consumption of soil organic carbon in interior Alaska: Implications for black carbon accumulation , 2007 .

[14]  Kenji Yoshikawa,et al.  Impacts of wildfire on the permafrost in the boreal forests of Interior Alaska , 2002 .

[15]  Eric S. Kasischke,et al.  Resilience of Alaska's Boreal Forest to Climatic Change , 2010 .

[16]  M. Torre Jorgenson,et al.  Resilience and vulnerability of permafrost to climate change , 2010 .

[17]  K. Moffett,et al.  Remote Sens , 2015 .

[18]  A. D. McGuire,et al.  Recent Changes in Annual Area Burned in Interior Alaska: The Impact of Fire Management , 2015 .

[19]  Eric S. Kasischke,et al.  Remote monitoring of spatial and temporal surface soil moisture in fire disturbed boreal forest ecosystems with ERS SAR imagery , 2007 .

[20]  Yuri Shur,et al.  Reorganization of vegetation, hydrology and soil carbon after permafrost degradation across heterogeneous boreal landscapes , 2013 .

[21]  Eric S. Kasischke,et al.  Assessing spatial and temporal variations in surface soil moisture in fire-disturbed black spruce forests in Interior Alaska using spaceborne synthetic aperture radar imagery — Implications for post-fire tree recruitment , 2007 .

[22]  B. McCune,et al.  Analysis of Ecological Communities , 2002 .

[23]  F. Stuart Chapin,et al.  Fire severity mediates climate-driven shifts in understorey community composition of black spruce stands of interior Alaska , 2011 .

[24]  Vladimir E. Romanovsky,et al.  Numerical modeling of permafrost dynamics in Alaska using a high spatial resolution dataset , 2009 .

[25]  Leslie A. Viereck,et al.  Forest ecosystems in the Alaskan taiga. A synthesis of structure and function. , 1986 .

[26]  J. Qu,et al.  NMDI: A normalized multi‐band drought index for monitoring soil and vegetation moisture with satellite remote sensing , 2007 .

[27]  James E. McMurtrey,et al.  Temporal relationships between spectral response and agronomic variables of a corn canopy , 1981 .

[28]  I. Moore,et al.  Digital terrain modelling: A review of hydrological, geomorphological, and biological applications , 1991 .

[29]  R. Striegl,et al.  Rapid runoff via shallow throughflow and deeper preferential flow in a boreal catchment underlain by frozen silt (Alaska, USA) , 2013, Hydrogeology Journal.

[30]  Samuel Rieger,et al.  Soil Survey: Fairbanks Area, Alaska , 1963 .

[31]  Douglas L. Kane,et al.  Progress in permafrost hydrology in the new millennium , 2008 .

[32]  Julia Boike,et al.  Satellite-based modeling of permafrost temperatures in a tundra lowland landscape , 2013 .

[33]  M. Torre Jorgenson,et al.  Permafrost Degradation and Ecological Changes Associated with a WarmingClimate in Central Alaska , 2001 .

[34]  M. Torre Jorgenson,et al.  Remote sensing and field‐based mapping of permafrost distribution along the Alaska Highway corridor, interior Alaska , 2010 .

[35]  D. M. Lawrence,et al.  Climate change and the permafrost carbon feedback , 2014, Nature.

[36]  E. W. Shaw,et al.  Department of the Interior , 1986, The Bulletin of the Ecological Society of America.

[37]  Jeremy B. Jones,et al.  The long-term response of stream flow to climatic warming in headwater streams of interior Alaska 1 , 2010 .

[38]  M. Claverie,et al.  Preliminary analysis of the performance of the Landsat 8/OLI land surface reflectance product. , 2016, Remote sensing of environment.

[39]  Claude R. Duguay,et al.  Using the MODIS land surface temperature product for mapping permafrost: an application to northern Québec and Labrador, Canada , 2009 .

[40]  B. Wylie,et al.  On the terminology of the spectral vegetation index (NIR − SWIR)/(NIR + SWIR) , 2011 .

[41]  J. Braun-Blanquet,et al.  Plant Sociology: the Study of Plant Communities , 1983, Nature.

[42]  Yu Zhang,et al.  Transient projections of permafrost distribution in Canada during the 21st century under scenarios of climate change , 2008 .

[43]  David K. Swanson,et al.  Susceptibility of Permafrost Soils to Deep Thaw after Forest Fires in Interior Alaska, U.S.A., and Some Ecologic Implications , 1996 .

[44]  Christopher A. Hiemstra,et al.  Interactive effects of wildfire and climate on permafrost degradation in Alaskan lowland forests , 2015 .

[45]  Leslie A. Viereck,et al.  The Alaska vegetation classification. , 1992 .

[46]  R. Hall,et al.  Using Landsat data to assess fire and burn severity in the North American boreal forest region: an overview and summary of results , 2008 .

[47]  A. McGuire,et al.  Modeling fire severity in black spruce stands in the Alaskan boreal forest using spectral and non-spectral geospatial data. , 2010 .

[48]  Y. Kerr Soil moisture from space: Where are we? , 2007 .

[49]  M. Jorgenson,et al.  Response of boreal ecosystems to varying modes of permafrost degradation , 2005 .

[50]  Andrew O. Finley,et al.  Permafrost and organic layer interactions over a climate gradient in a discontinuous permafrost zone , 2013 .

[51]  F. Stuart Chapin,et al.  Fire Severity Filters Regeneration Traits to Shape Community Assembly in Alaska’s Boreal Forest , 2013, PloS one.

[52]  Bruce K. Wylie,et al.  Evidence for nonuniform permafrost degradation after fire in boreal landscapes , 2016 .

[53]  Eric S. Kasischke,et al.  Persistent Effects of Fire Severity on Early Successional Forests in Interior Alaska , 2011 .

[54]  A. McGuire,et al.  Alaska's Changing Fire Regime - Implications for the Vulnerability of Its Boreal Forests , 2010 .

[55]  T. N. V. Karlstrom,et al.  Surficial geology of Alaska , 1964 .

[56]  Clifford I. Voss,et al.  Airborne electromagnetic imaging of discontinuous permafrost , 2012 .

[57]  Elchin Jafarov,et al.  The effects of fire on the thermal stability of permafrost in lowland and upland black spruce forests of interior Alaska in a changing climate , 2013 .