Multiscale modeling of spring phenology across Deciduous Forests in the Eastern United States
Autor: | Eli K. Melaas, Mark A. Friedl, Andrew D. Richardson |
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Rok vydání: | 2016 |
Předmět: |
Satellite Imagery
0106 biological sciences Canopy 010504 meteorology & atmospheric sciences Rain Forcing (mathematics) Forests Temperate deciduous forest Atmospheric sciences 010603 evolutionary biology 01 natural sciences Trees Photography Environmental Chemistry Ecosystem 0105 earth and related environmental sciences General Environmental Science Global and Planetary Change Ecology Phenology Temperature Models Theoretical Radiative forcing Multiscale modeling United States Plant Leaves Deciduous Environmental science Seasons |
Zdroj: | Global Change Biology. 22:792-805 |
ISSN: | 1365-2486 1354-1013 |
DOI: | 10.1111/gcb.13122 |
Popis: | Phenological events, such as bud burst, are strongly linked to ecosystem processes in temperate deciduous forests. However, the exact nature and magnitude of how seasonal and interannual variation in air temperatures influence phenology is poorly understood, and model-based phenology representations fail to capture local- to regional-scale variability arising from differences in species composition. In this paper, we use a combination of surface meteorological data, species composition maps, remote sensing, and ground-based observations to estimate models that better represent how community-level species composition affects the phenological response of deciduous broadleaf forests to climate forcing at spatial scales that are typically used in ecosystem models. Using time series of canopy greenness from repeat digital photography, citizen science data from the USA National Phenology Network, and satellite remote sensing-based observations of phenology, we estimated and tested models that predict the timing of spring leaf emergence across five different deciduous broadleaf forest types in the eastern United States. Specifically, we evaluated two different approaches: (i) using species-specific models in combination with species composition information to 'upscale' model predictions and (ii) using repeat digital photography of forest canopies that observe and integrate the phenological behavior of multiple representative species at each camera site to calibrate a single model for all deciduous broadleaf forests. Our results demonstrate variability in cumulative forcing requirements and photoperiod cues across species and forest types, and show how community composition influences phenological dynamics over large areas. At the same time, the response of different species to spatial and interannual variation in weather is, under the current climate regime, sufficiently similar that the generic deciduous forest model based on repeat digital photography performed comparably to the upscaled species-specific models. More generally, results from this analysis demonstrate how in situ observation networks and remote sensing data can be used to synergistically calibrate and assess regional parameterizations of phenology in models. |
Databáze: | OpenAIRE |
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