97th ESA Annual Meeting (August 5 -- 10, 2012)

PS 90-38 - Abiotic drivers of taxonomic and functional diversity along an altitudinal gradient in tropical montane forest of Costa Rica

Friday, August 10, 2012
Exhibit Hall, Oregon Convention Center
Chelsea M. Robinson1, Sassan S. Saatchi2, David B. Clark3, Geoffrey A. Fricker1, Jeffrey A. Wolf4, Corey M. Rovzar5, Thomas W. Gillespie5, Stephen P. Hubbell4 and Sandy Andelman6, (1)Geography, University of California, Los Angeles, Los Angeles, CA, (2)Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA, (3)Depts. of Biology & Environmental Sciences, University of Missouri-St. Louis & University of Virginia, La Selva, Costa Rica, (4)Ecology and Evolutionary Biology, UCLA, Los Angeles, CA, (5)University of California, Los Angeles, (6)Tropical Ecology Assessment and Monitoring (TEAM), Conservation International, Arlington, VA
Background/Question/Methods

This research sought to understand how alpha and beta diversity of plants vary and relate to the three-dimensional vegetation structure and functional diversity along environmental gradients in the tropical montane forests of Braulio Carrillo National Park in Costa Rica. There is growing evidence that ecosystem structure plays an important role in defining patterns of species diversity and along with abiotic factors (climate and edaphic) control the phenotypic and functional variations across landscapes. It is well documented that strong subdivisions at local and regional scales are found mainly on geologic or climate gradients. These general determinants of biodiversity are best demonstrated in regions with natural gradients such as tropical montane forests. Altitudinal gradients provide a landscape scale changes through variations in topography, climate, and edaphic conditions on which we tested several theoretical and biological hypotheses regarding drivers of biodiversity.  The study was performed by using forest inventory and botanical data from nine 1-ha plots ranging from 100 m to 2800 m above sea level and remote sensing data from airborne Lidar and Radar sensors to quantify variations in forest structure. 

Results/Conclusions

In this study we report on the effectiveness of relating patterns of tree taxonomic and functional diversity to three-dimensional structure of a tropical montane forest at varying spatial scales using remote sensing observations of forest structure. We assessed a and b diversity at the species, genus, and family levels utilizing datasets provided by the Terrestrial Ecology Assessment and Monitoring (TEAM) Network. Through the comparison to active remote sensing imagery, our results show that there is a strong relationship between forest 3D-structure, and alpha and beta diversity controlled by variations in abiotic factors along the altitudinal gradient. Using spatial analysis with the aid of remote sensing data, we find distinct patterns along the environmental gradients defining species turnover and changes in functional diversity. The study will provide novel approaches to use detailed spatial information from remote sensing data to study relations between functional and taxonomic dimensions of diversity.