Abstract
Salinity normalization of total alkalinity (TA) and dissolved inorganic carbon (DIC) data is commonly used to account for conservative mixing processes when inferring net metabolic modification of seawater by coral reefs. Salinity (S), TA, and DIC can be accurately and precisely measured, but salinity normalization of TA (nTA) and DIC (nDIC) can generate considerable and unrecognized uncertainties in coral reef metabolic rate estimates. While salinity normalization errors apply to nTA, nDIC, and other ions of interest in coral reefs, here, we focus on nTA due to its application as a proxy for net coral reef calcification and the importance for reefs to maintain calcium carbonate production under environmental change. We used global datasets of coral reef TA, S, and modeled groundwater discharge to assess the effect of different volumetric ratios of multiple freshwater TA inputs (i.e., groundwater, river, surface runoff, and precipitation) on nTA. Coral reef freshwater endmember TA ranged from -2 up to 3032 μmol/kg in hypothetical reef locations with freshwater inputs dominated by riverine, surface runoff, or precipitation mixing with groundwater. The upper bound of freshwater TA in these scenarios can result in an uncertainty in reef TA of up to 90 μmol/kg per unit S normalization if the freshwater endmember is erroneously assumed to have 0 μmol/kg alkalinity. The uncertainty associated with S normalization can, under some circumstances, even shift the interpretation of whether reefs are net calcifying to net dissolving, or vice versa. Moreover, the choice of reference salinity for normalization implicitly makes assumptions about whether biogeochemical processes occur before or after mixing between different water masses, which can add uncertainties of ±1.4% nTA per unit S normalization. Additional considerations in identifying potential freshwater sources of TA and their relative volumetric impact on seawater are required to reduce uncertainties associated with S normalization of coral reef carbonate chemistry data in some environments. However, at a minimum, researchers should minimize the range of salinities over which the normalization is applied, precisely measure salinity, and normalize TA values to a carefully selected reference salinity that takes local factors into account.
Highlights
Coral reef metabolic measurements are important tools used to quantify a reef’s carbon cycle, health and function, and responses to ongoing environmental change
We provide a series of suggestions to reduce the uncertainties associated with salinity normalization of coral reef total alkalinity (TA) data with implications for other carbonate chemistry parameters and ions of interest to coral reef metabolism studies (e.g., dissolved inorganic carbon (DIC), Ca2+, Mg2+, etc.)
Coral reef TAS = 0 estimates were positively skewed with median (2.5th to 97.5th percentile) values of 15 μmol/L (-2 to 1997 μmol/L) for groundwater mixing with precipitation, 1306 μmol/L (293 to 2979 μmol/L) for groundwater mixing with river water, and 598 μmol/L (43 to 2507 μmol/L) for groundwater mixing with surface runoff (Fig 2E)
Summary
Coral reef metabolic measurements are important tools used to quantify a reef’s carbon cycle, health and function, and responses to ongoing environmental change. We quantify the potential uncertainties in ΔnTA associated with the salinity normalization of coral reef total alkalinity to unknown freshwater endmembers (TAS = 0) and reference salinities (Sref) using global seawater TA and S, fresh submarine groundwater discharge, a range of different TAS = 0 datasets, and different mixing proportions of freshwater endmembers.
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