GC52D-05
Variability in reef connectivity in the Coral Triangle

Friday, 18 December 2015: 11:20
3003 (Moscone West)
Diane M Thompson1, J A Kleypas1, Frederic S Castruccio1, James R. Watson2 and Enrique N Curchitser3, (1)National Center for Atmospheric Research, Climate and Global Dynamics, Boulder, CO, United States, (2)Stockholm University, Stockholm Resilience Centre, Stockholm, Sweden, (3)Rutgers University New Brunswick, Department of Environmental Sciences, New Brunswick, NJ, United States
Abstract:
The Coral Triangle (CT) is not only the global center of marine biodiversity, it also supports the livelihoods of millions of people. Unfortunately, it is also considered the most threatened of all reef regions, with rising temperature and coral bleaching already taking a toll. Reproductive connectivity between reefs plays a critical role in the reef’s capacity to recover after such disturbances. Thus, oceanographic modeling efforts to understand patterns of reef connectivity are essential to the effective design of a network of Marine Protected Areas (MPAs) to conserve marine ecosystems in the Coral Triangle. Here, we combine a Regional Ocean Modeling System developed for the Coral Triangle (CT-ROMS) with a Lagrangian particle tracking tool (TRACMASS) to investigate the probability of coral larval transport between reefs. A 47-year hindcast simulation (1960-2006) was used to investigate the variability in larval transport of a broadcasting coral following mass spawning events in April and September. Potential connectivity between reefs was highly variable and stochastic from year to year, emphasizing the importance of decadal or longer simulations in identifying connectivity patterns, key source and sink regions, and thus marine management targets for MPAs. The influence of temperature on realized connectivity (future work) may add further uncertainty to year-to-year patterns of connectivity between reefs. Nonetheless, the potential connectivity results we present here suggest that although reefs in this region are primarily self-seeded, rare long-distance dispersal may promote recovery and genetic exchange between reefs in the region. The spatial pattern of “subpopulations” based solely on the physical drivers of connectivity between reefs closely match regional patterns of biodiversity, suggesting that physical barriers to larval dispersal may be a key driver of reef biodiversity. Finally, 21st Century simulations driven by the Community Earth System Model (CESM) suggest that these major barriers to larval dispersal persist into the future under 8.5 W/m2 of climate forcing, despite some regional changes in connectivity between reefs.