Remote Sensing Based Simple Models of GPP in Both Disturbed and Undisturbed Piñon-Juniper Woodlands in the Southwestern U.S

Remote sensing is a key technology that enables us to scale up our empirical, in situ measurements of carbon uptake made at the site level. In low leaf area index ecosystems typical of semi-arid regions however, many assumptions of these remote sensing approaches fall short, given the complexities of the heterogeneous landscape and frequent disturbance. Here, we investigated the utility of remote sensing data for predicting gross primary production (GPP) in pinon-juniper woodlands in New Mexico (USA). We developed a simple model hierarchy using climate drivers and satellite vegetation indices (VIs) to predict GPP, which we validated against in situ estimates of GPP from eddy-covariance. We tested the influence of pixel size on model fit by comparing model performance when using VIs from RapidEye (5 m) and the VIs from Landsat ETM+ (30 m). We also tested the ability of the normalized difference wetness index (NDWI) and normalized difference red edge (NDRE) to improve model fits. The best predictor of GPP at the undisturbed PJ woodland was Landsat ETM+ derived NDVI (normalized difference vegetation index), whereas at the disturbed site, the red-edge VI performed best (R2adj of 0.92 and 0.90 respectively). The RapidEye data did improve model performance, but only after we controlled for the variability in sensor view angle, which had a significant impact on the apparent cover of vegetation in our low fractional cover experimental woodland. At both sites, model performance was best either during non-stressful growth conditions, where NDVI performed best, or during severe ecosystem stress conditions (e.g., during the girdling process), where NDRE and NDWI improved model fit, suggesting the inclusion of red-edge leveraging and moisture sensitive VI in simple, data driven models can constrain GPP estimate uncertainty during periods of high ecosystem stress or disturbance.

[1]  Kathryn Sheffield,et al.  Comparing inter-sensor NDVI for the analysis of horticulture crops in south-eastern Australia , 2014 .

[2]  G. Katul,et al.  An approximate analytical model for footprint estimation of scalar fluxes in thermally stratified atmospheric flows , 2000 .

[3]  Paul E. Gessler,et al.  Sensitivity of Ground‐Based Remote Sensing Estimates of Wheat Chlorophyll Content to Variation in Soil Reflectance , 2009 .

[4]  Yi Y. Liu,et al.  Contribution of semi-arid ecosystems to interannual variability of the global carbon cycle , 2014, Nature.

[5]  Susan L. Ustin,et al.  Spectral sensing of foliar water conditions in two co-occurring conifer species: Pinus edulis and Ju , 2005 .

[6]  Chih-Ling Tsai,et al.  MODEL SELECTION FOR MULTIVARIATE REGRESSION IN SMALL SAMPLES , 1994 .

[7]  R. Seager,et al.  Temperature as a potent driver of regional forest drought stress and tree mortality , 2013 .

[8]  R. Seager,et al.  Model Projections of an Imminent Transition to a More Arid Climate in Southwestern North America , 2007, Science.

[9]  W. Oechel,et al.  A new model of gross primary productivity for North American ecosystems based solely on the enhanced vegetation index and land surface temperature from MODIS , 2008 .

[10]  A. Gitelson,et al.  Quantitative estimation of chlorophyll-a using reflectance spectra : experiments with autumn chestnut and maple leaves , 1994 .

[11]  Marcy E. Litvak,et al.  Differential responses of production and respiration to temperature and moisture drive the carbon balance across a climatic gradient in New Mexico , 2011 .

[12]  G. Katul,et al.  Soil moisture and vegetation controls on evapotranspiration in a heterogeneous Mediterranean ecosystem on Sardinia, Italy , 2006 .

[13]  G. Carter,et al.  Early detection of plant stress by digital imaging within narrow stress-sensitive wavebands , 1994 .

[14]  K. Davis,et al.  Global estimates of evapotranspiration and gross primary production based on MODIS and global meteorology data , 2010 .

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

[16]  D. Sims,et al.  An improved approach for remotely sensing water stress impacts on forest C uptake , 2014, Global change biology.

[17]  A. Arneth,et al.  Separation of net ecosystem exchange into assimilation and respiration using a light response curve approach: critical issues and global evaluation , 2010 .

[18]  Lawrence B. Flanagan,et al.  Seasonal and interannual variation in carbon dioxide exchange and carbon balance in a northern temperate grassland , 2002 .

[19]  J. Monteith SOLAR RADIATION AND PRODUCTIVITY IN TROPICAL ECOSYSTEMS , 1972 .

[20]  D. Roy,et al.  Web-enabled Landsat Data (WELD): Landsat ETM+ composited mosaics of the conterminous United States , 2010 .

[21]  N. McDowell,et al.  A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests , 2010 .

[22]  Piero Toscano,et al.  Remote sensing of annual terrestrial gross primary productivity from MODIS: an assessment using the FLUXNET La Thuile data set , 2013 .

[23]  R. Jackson,et al.  Spectral response of a plant canopy with different soil backgrounds , 1985 .

[24]  C. Tucker Red and photographic infrared linear combinations for monitoring vegetation , 1979 .

[25]  B. Rock,et al.  Detection of changes in leaf water content using Near- and Middle-Infrared reflectances , 1989 .

[26]  K. Price,et al.  Regional vegetation die-off in response to global-change-type drought. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[27]  G. Yohe,et al.  Climate Change Impacts in the United States: The Third National Climate Assessment , 2014 .

[28]  Neil S. Cobb,et al.  Drought induced tree mortality and ensuing bark beetle outbreaks in southwestern pinyon-juniper woodlands , 2008 .

[29]  S. Goward,et al.  Characterization of the Landsat-7 ETM Automated Cloud-Cover Assessment (ACCA) Algorithm , 2006 .

[30]  J. Eitel,et al.  Suitability of existing and novel spectral indices to remotely detect water stress in Populus spp. , 2006 .

[31]  E. Hunt,et al.  Combined Spectral Index to Improve Ground‐Based Estimates of Nitrogen Status in Dryland Wheat , 2008 .

[32]  Ramakrishna R. Nemani,et al.  MODIS-Derived Terrestrial Primary Production , 2010 .

[33]  D. Breshears,et al.  Precipitation thresholds and drought-induced tree die-off: insights from patterns of Pinus edulis mortality along an environmental stress gradient. , 2013, The New phytologist.

[34]  Gregg M. Garfin,et al.  Ch. 20: Southwest. Climate Change Impacts in the United States: The Third National Climate Assessment , 2014 .

[35]  E. K. Webb,et al.  Correction of flux measurements for density effects due to heat and water vapour transfer , 1980 .

[36]  J. Eitel,et al.  Using in‐situ measurements to evaluate the new RapidEye™ satellite series for prediction of wheat nitrogen status , 2007 .

[37]  G. Carter,et al.  Leaf optical properties in higher plants: linking spectral characteristics to stress and chlorophyll concentration. , 2001, American journal of botany.

[38]  K. Hibbard,et al.  A Global Terrestrial Monitoring Network Integrating Tower Fluxes, Flask Sampling, Ecosystem Modeling and EOS Satellite Data , 1999 .

[39]  W. Massman A simple method for estimating frequency response corrections for eddy covariance systems , 2000 .

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

[41]  J. Monteith Climate and the efficiency of crop production in Britain , 1977 .

[42]  Atul K. Jain,et al.  The dominant role of semi-arid ecosystems in the trend and variability of the land CO2 sink , 2015, Science.

[43]  Frank W. Davis,et al.  Viewing Geometry of AVHRR Image Composites Derived Using Multiple Criteria , 1997 .

[44]  Urs Schulthess,et al.  Detecting mortality induced structural and functional changes in a piñon-juniper woodland using Landsat and RapidEye time series , 2014 .

[45]  Dorothy K. Hall,et al.  Assessment of Snow-Cover Mapping Accuracy in a Variety of Vegetation-Cover Densities in Central Alaska , 1998 .

[46]  Stanley B. Brown,et al.  THE DEGRADATION OF CHLOROPHYLL - A BIOLOGICAL ENIGMA. , 1987, The New phytologist.

[47]  R. Fensholt,et al.  Evaluation of satellite based primary production modelling in the semi-arid Sahel , 2006 .

[48]  James P. Verdin,et al.  Evaluation of MODIS NDVI and NDWI for vegetation drought monitoring using Oklahoma Mesonet soil moisture data , 2008 .

[49]  R. Leuning,et al.  Carbon and water fluxes over a temperate Eucalyptus forest and a tropical wet/dry savanna in Australia: measurements and comparison with MODIS remote sensing estimates , 2005 .

[50]  Alan A. Ager,et al.  Broadband, red-edge information from satellites improves early stress detection in a New Mexico conifer woodland , 2011 .

[51]  Naomi Naik,et al.  Does Global Warming Cause Intensified Interannual Hydroclimate Variability , 2012 .

[52]  Dan S. Long,et al.  Active Ground Optical Remote Sensing for Improved Monitoring of Seedling Stress in Nurseries , 2010, Sensors.