Dr. Steve Oberbauer, of FIU's Biology Department, has just received two significant grants from the National Science Foundation.

 National Science Foundation – Polar Programs. Arctic Observing Networks: Collaborative Research: Sustaining and amplifying the ITEX AON through automation and increased interdisciplinarity of observations.

The International Tundra Experiment (ITEX) Arctic Observing Network (AON) collects data on phenology, plant growth, community composition and ecosystem properties as part of a greater effort to study environmental change in the Arctic. The network, started in early 1990’s, now provides tremendous value for detecting changes within long-term experimentally warmed and control plots across a range of sites and ecosystems that span the major vegetation types of the Arctic. While of great value, these manually collected measurements are labor intensive and time consuming, greatly restricting frequency and spatial extent of sampling. Recent advances in sensor technology hold the promise to allow sampling of surrogates of these manual measurements rapidly and over large areas. Here we will continue the ITEX AON observations and initiate a suite of related, non-intrusive structure, reflectance and thermal measurements using robotic sensor platforms (networked infomechanical systems, NIMS). These new measurements will allow us to scale our measurements to the regional level by linking to existing 1 km2 sample vegetation grids and to satellite imagery, providing urgently needed data critical to our understanding of the impacts of changing tundra vegetation on the interactions between the land and the atmosphere for the Arctic and the global system, including carbon and water fluxes and energy balance.

National Science Foundation – Ecosystems. Causes and implications of dry season control of tropical wet forest tree growth at very high water levels: direct vs. indirect limitations.

Recent research in Costa Rica has shown that the growth of tropical moist forest trees is strongly related to the strength of the dry season across a range of rainfall that by all standard measures would be considered more than sufficient for growth. Understanding the basis for this finding is crucial because tropical moist forests play important roles in the global carbon and water cycles and therefore regional and global climate. Predicted future warming and drying of tropical moist forests could have strong feedback effects on global climate. However, recent satellite studies from the Amazon report that trees have their greatest leaf cover during the dry season, suggesting that the dry season does not affect production. These two findings suggest a serious gap in our understanding of role of the dry season on tropical tree growth and carbon sequestration. Dry-season controls on tree growth could result from both direct water limitation or via other indirect mechanisms. This project will test hypotheses of direct water limitation and indirect mechanisms to determine the basis for the dry season rainfall correlation with growth. The study will use both observational and experimental approaches to test for direct and indirect water limitation. Measurements of growth and ecosystem carbon, water and energy balance will be used to evaluate the importance of dry season growth reduction for regional climate.