The oxygen isotopic composition of phosphate in Elkhorn Slough, California: A tracer for phosphate sources

Elkhorn Slough, a small seasonal estuary in central California, has been subjected to increased nutrient loading from agricultural and other non-point sources. However, because nutrients do not behave conservatively, tracing nutrient sources and cycling in ecosystems like Elkhorn Slough has been difficult to assess. This is particularly true of phosphorus (P), which has only one stable isotope and cannot be used as an isotopic tracer. However, isotopic fractionation of oxygen in phosphate at surface water temperatures only occurs as a result of enzyme-mediated, biochemical reactions. Thus, if phosphate demand is low relative to input and is not heavily cycled within the ecosystem, the δ¹⁸O of phosphate will reflect the isotopic composition of phosphate sources to the system. We utilized the δ¹⁸O of dissolved inorganic phosphate (DIP) within the main channel of the slough and nearby Moss Landing Harbor and the δ¹⁸O of reactive phosphate from sediment and soil samples collected within the watershed to understand phosphate sources and cycling within Elkhorn Slough. Trends in the δ¹⁸O of DIP were seasonally consistent with high values near the mouth reflecting oceanic phosphate (19.1‰-20.3‰), dropping to a minimum value near Hummingbird Island in the central slough (point source, 14.1‰-14.4‰), and increasing again near the head of the slough, reflecting fertilizer input (18.9‰-19.3‰). Reactive phosphate δ¹⁸O values extracted from sediments and soils in the watershed range from 10.6‰ in a drainage ditch to 22.3‰ in creek sediments near agriculture fields. The wide range in phosphate δ¹⁸O values reflects the variations in land use and application of different fertilizers in this agriculturally dominated landscape. These data suggest that phosphate δ¹⁸O can be an effective tool for identifying P sources and understanding phosphate dynamics in estuarine ecosystems.