Automated cavity ring down spectroscopy was used to make continuous measurements of dissolved methane, nitrous oxide, and carbon dioxide in a coral reef lagoon for 2 weeks (Heron Island, Great Barrier Reef). Radon (222Rn) was used to trace the influence of tidally driven pore water exchange on greenhouse gas dynamics. Clear tidal variation was observed for CH4, which correlated to 222Rn in lagoon waters. N2O correlated to 222Rn during the day only, which appears to be a response to coupled nitrification-denitrification in oxic sediments, fueled by nitrate derived from bird guano. The lagoon was a net source of CH4 and N2O to the atmosphere and a sink for atmospheric CO2. The estimated pore water-derived CH4 and N2O fluxes were 3.2-fold and 24.0-fold greater than the fluxes to the atmosphere. Overall, pore water and/or groundwater exchange were the only important sources of CH4 and major controls of N2O in the coral reef lagoon.
Journal article
Nitrous oxide and methane dynamics in a coral reef lagoon driven by pore water exchange: insights from automated high-frequency observations
Geophysical Research Letters, Vol.42(8), pp.2885-2892
2015
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Abstract
Details
- Title
- Nitrous oxide and methane dynamics in a coral reef lagoon driven by pore water exchange: insights from automated high-frequency observations
- Creators
- Chiara O'Reilly - Southern Cross UniversityIsaac R Santos - Southern Cross UniversityTyler Cyronak - Southern Cross UniversityAshley McMahon - Southern Cross UniversityDamien T Maher - Southern Cross University
- Publication Details
- Geophysical Research Letters, Vol.42(8), pp.2885-2892
- Identifiers
- 3533; 991012821146602368
- Academic Unit
- National Marine Science Centre; Centre for Coastal Biogeochemistry; School of Environment, Science and Engineering; Faculty of Science and Engineering; Science
- Resource Type
- Journal article