B51B-0433
High-resolution chemical and hydrologic records identify environmental factors that control coastal anchialine cave ecosystem function

Friday, 18 December 2015
Poster Hall (Moscone South)
David Brankovits1, John Pohlman2, Laura Lapham3, Michael Casso2, Eric Roth4, Nicholas S Lowell5 and Thomas M. Iliffe1, (1)Texas A & M University at Galveston, Galveston, TX, United States, (2)USGS Coastal and Marine Science Center Woods Hole, Woods Hole, MA, United States, (3)UMCES, Chesapeake Bio. Lab, Solomons, MD, United States, (4)Onset Computer Corporation, Bourne, MA, United States, (5)Lowell Instruments LLC, Engineering, North Falmouth, MA, United States
Abstract:
Anchialine caves host a coastal aquifer ecosystem occupied by cave-adapted crustaceans that reside within distinct fresh, brackish and marine waters. Our initial investigation of this subsurface ecotone in the Yucatan Peninsula (Mexico) provides stable isotope-based evidence that methane and dissolved organic carbon (DOC) are the primary sources of energy and carbon for the food web. However, the frequency of observations is sparse, leaving us ‘in the dark’ with respect to the temporal dynamics of the ecosystem function. In this study, we obtained undisturbed vertical profiles of methane, DOC and DIC concentration and isotopic composition with the ‘Octopipi’ water sampler from an anchialine cave located ~8 km from the coastline. To document the temporal variability of methane availability in the cave, we deployed an osmotically-driven pump (OsmoSampler). Data loggers recorded dissolved oxygen (DO), salinity, temperature and current velocities, and a rain gauge recorded precipitation. A high-methane water mass near the ceiling (up to 7795 nM) contained elevated concentration (900 µM), 13C-depleted (-27.8 to -28.2 ‰) DOC, suggesting terrestrial organic matter input from the overlying soils. Low-methane saline water (36 to 84 nM) had lower concentration DOC (15 to 97 µM) with a similar δ13C (-25.9 to -27.2 ‰), suggesting significant terrestrial organic matter consumption or removal with increasing depth, from fresh to saline water, within the water column. Our 6-month water chemistry record reveals high concentrations of methane in the wet season, especially following rainfall events, and relatively lower methane concentrations in the dry season. These observations suggest rain flushes methane generated in overlying anoxic soils into the cave. DO, water level, and groundwater flow patterns were also linked to the precipitation record. These data provide novel insight into the interconnections between external climate forcing and subterranean anchialine ecosystems within coastal aquifers.