Abstract
Climate influences geographic differences of vegetation phenology through both contemporary and historical variability. The latter effect is embodied in vegetation heterogeneity underlain by spatially varied genotype and species compositions tied to climatic adaptation. Such long-term climatic effects are difficult to map and therefore often neglected in evaluating spatially explicit phenological responses to climate change. In this study we demonstrate a way to indirectly infer the portion of land surface phenology variation that is potentially contributed by underlying genotypic differences across space. The method undertaken normalized remotely sensed vegetation start-of-season (or greenup onset) with a cloned plants-based phenological model. As the geography of phenological model prediction (first leaf) represents the instantaneous effect of contemporary climate, the normalized land surface phenology potentially reveals vegetation heterogeneity that is related to climatic adaptation. The study was done at the continental scale for the conterminous U.S., with a focus on the eastern humid temperate domain. Our findings suggest that, in an analogous scenario, if a uniform contemporary climate existed everywhere, spring vegetation greenup would occur earlier in the north than in the south. This is in accordance with known species-level clinal variations—for many temperate plant species, populations adapted to colder climates require less thermal forcing to initiate growth than those in warmer climates. This study, for the first time, shows that such geographic adaption relationships are supported at the ecosystem level. Mapping large-scale vegetation climate adaptation patterns contributes to our ability to better track geographically varied phenological responses to climate change.
Highlights
Temperate vegetation phenology demonstrates large spatiotemporal variations that are controlled simultaneously by current climatic variability and underlying plant heterogeneity
While much attention has been drawn to temporal variations of phenology in response to climate change [1,2], we have not been able to effectively account for spatial variations of phenological response that are caused by intra- and inter-specific differences [3,4]
We generally recommend CAIND for potential future use as far as the units are not of concern for intended applications. This does not rule out the utility of CAIDIF and CAI based on division (CAIDIV), which may turn out to be more straightforward in particular cases
Summary
Temperate vegetation phenology demonstrates large spatiotemporal variations that are controlled simultaneously by current climatic variability and underlying plant heterogeneity. The latter is shaped by genetic differentiation of plants via adaptation to past long-term climate gradients. Phenology of diverse plant populations varies phenotypically and temporally in response to current climate, and genotypically and spatially due to long-term climate impacts, as reflected by differing climatic requirements of different genotypes for growth and development, such as varied amounts of thermal forcing (e.g., warm temperature accumulation or growing degree days) needed to trigger bud burst [9,10]. Many woody species have shown lower forcing and higher chilling requirements for spring phenology within populations adapted to colder climates [11,12,13,14,15]. The effect of photoperiod on spring phenology, in addition to being limited to a few species, is supplemental to temperature [22]
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