CitationDannenberg, Matthew P.; Song, Conghe H.; Hwang, Taehee; & Wise, Erika K. (2015). Empirical Evidence of El Nino-Southern Oscillation Influence on Land Surface Phenology and Productivity in the Western United States. Remote Sensing of Environment, 159, 167-180.
AbstractTiming of plant life cycle events (phenology) and annual plant productivity represent key interactions between the climate system and the biosphere, with implications and feedbacks for climate and ecosystem functions. The El Nino-Southern Oscillation (ENSO) system is a dominant source of interannual climate variability in the western United States, with important effects on temperature, precipitation, and drought. In this study, we examine the connection between ENSO and terrestrial vegetation dynamics using MOD17 annual net primary productivity (NPP) and land surface phenology derived from MODIS and AVHRR vegetation indices. Three phenology metrics-start of growing season (SOS), end of growing season (EOS), and length of growing season (LOS)-were estimated separately for El Nino and La Nina years by fitting difference logistic functions to split-sample time series of the MODIS enhanced vegetation index (for the period 2000-2011) and AVHRR-derived 3rd generation GIMMS NDVI (NDVI3g) for two temporal periods (2000-2011 and 1982-2011). El Nino events were associated with a significantly earlier SOS than La Nina events in most regions of the western U.S. ENSO-related differences in timing of the end of growing season were generally smaller and more heterogeneous. ENSO impacts on total length of the growing season tended to be spatially heterogeneous but mostly positive in El Nino years. Relative to La Nina events, El Nino events were generally associated with significantly higher NPP in each ecoregion (with mean differences ranging from 2 to 45 gC m(-2) year(-1)). The correlation between total annual production and the Southern Oscillation Index was highest in mid- to late-winter prior to the growing season, suggesting some predictive power in advance of the growing season. These results suggest that future intensification of the ENSO system could have serious consequences for terrestrial ecosystems in the western U.S., especially in regions where ENSO already has a strong impact on interannual climate variability and vegetation dynamics.
Reference TypeJournal Article
Journal TitleRemote Sensing of Environment
Author(s)Dannenberg, Matthew P.
Song, Conghe H.
Wise, Erika K.