Abstract
Abstract. To better predict how ocean acidification will affect coral reefs, it is important to understand how biogeochemical cycles on reefs alter carbonate chemistry over various temporal and spatial scales. This study quantifies the contribution of shallow porewater exchange (as quantified from advective chamber incubations) and fresh groundwater discharge (as traced by 222Rn) to total alkalinity (TA) dynamics on a fringing coral reef lagoon along the southern Pacific island of Rarotonga over a tidal and diel cycle. Benthic alkalinity fluxes were affected by the advective circulation of water through permeable sediments, with net daily flux rates of carbonate alkalinity ranging from −1.55 to 7.76 mmol m−2 d−1, depending on the advection rate. Submarine groundwater discharge (SGD) was a source of TA to the lagoon, with the highest flux rates measured at low tide, and an average daily TA flux of 1080 mmol m−2 d−1 at the sampling site. Both sources of TA were important on a reef-wide basis, although SGD acted solely as a delivery mechanism of TA to the lagoon, while porewater advection was either a sink or source of TA dependent on the time of day. This study describes overlooked sources of TA to coral reef ecosystems that can potentially alter water column carbonate chemistry. We suggest that porewater and groundwater fluxes of TA should be taken into account in ocean acidification models in order to properly address changing carbonate chemistry within coral reef ecosystems.
Highlights
The recent incMreaosedien latDmoesvpheelroicpCmO2ehnats led to an in-M ous temporal and spatial scales
Alkalinity concentrations in Muri Lagoon followed a pattern that is indicative of both biological and tidal drivers influencing the dynamics of water column total alkalinity (TA) over a diel cycle (Fig. 4)
Small-scale porewater advection acted as both a source and sink of TA over the course of a day, with net daily fluxes ranging from −1.55 to 7.76 mmol m−2 d−1 depending on advection rates
Summary
The recent incMreaosedien latDmoesvpheelroicpCmO2ehnats led to an in-M ous temporal and spatial scales. (tFoeealyreetdaulc.t,i2o0n04iSn; DcpoiHenenaytceateasrla.,te20o0f9)r.oOucgehalny through permeable sediments, with net daily flux rates of car- acidification can have drastic effects on biological processes bonate alkalinity ranging from −1.55 to 7.76 mmol m−2 d−1, and the biogeochemistry of marine ecosystems, with coral depending on the advection rate. TA flux of 1080 mmol m−2 d−1 at the sampling site Both chemistry of the overlying seawater, leading to large diel sources of TA were important on a reef-wide basis, variations in alkalinity, pCO2, pH, and dissolved oxygen. In order to understand how ocean acidification will affeSctocloidralEreaefrst,hit is important overlooked sources of TA to coral reef ecosystems that can to understand how natural processes, which can potentially potentially alter water column carbonate chemistry. We sug- buffer or intensify changes in seawater pH, alter the carbongest that porewater and groundwater fluxes of TA should be ate chemistry of seawater within coral reef ecosystems
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