Abstract

Accurately inferring plant functional trait composition, diversity, and redundancy across space and time is pivotal for understanding environmental change impacts on forests' biodiversity and functioning. Here, we tested the capabilities of combining in-situ and remote sensing approaches to deliver accurate estimates of functional trait composition, diversity, and redundancy of temperate forest vegetation in South America (30 degrees S to 53 degrees S) considering leaf and stem morphological, nutrient, hydraulic, and photosynthetic traits. We identified hydrological stress, soil properties, and topography as key drivers of plant functional trait distribution and variation. Further, hydrological stress and soil properties were key determinants of functional diversity and redundancy across a large latitudinal gradient. Functional diversity peaked across Mediterranean forests, occupying between 30 degrees S to 35 degrees S. Functional diversity and redundancy were both high at latitudes between 35 degrees S and 42 degrees S, coinciding with Valdivian rainforests. Conversely, functional redundancy peaked between 42 degrees S and 48 degrees S, corresponding to Austral forests. Towards the southernmost extent of the study area, functional diversity and redundancy were both low between 48 degrees S and 53 degrees S, corresponding to the Magellanic subpolar forests. Our results highlight areas in South American temperate forests where both plant functional diversity and redundancy were maximal, hence potentially pointing towards areas more resilient to environmental change.