Abstract

The response of estuarine ecosystems to long-term changes in external forcing is strongly mediated by interactions between the biogeochemical cycling of carbon, oxygen, and inorganic nutrients. Although long-term changes in estuaries are often assessed at the annual scale, phytoplankton biomass, dissolved oxygen concentrations, and biogeochemical rate processes have strong seasonal cycles at temperate latitudes. Thus, changes in the seasonal timing, or phenology, of these key processes can reveal important features of long-term change and help clarify the nature of coupling between carbon, oxygen, and nutrient cycles. Changes in the phenology of estuarine processes may be difficult to assess, however, because many organisms are mobile and migratory, key primary and secondary producers have relatively rapid physiological turnover rates, sampling in time and space is often limited, and physical processes may dominate variability. To overcome these challenges, we have analyzed a 32-year record (1985-2016) of relatively frequent and consistent measurements of chlorophyll-a, dissolved oxygen, nitrogen, and physical drivers to understand long-term change in Chesapeake Bay. Using a suite of metrics that directly test for altered phenology, we quantified changes in the seasonal timing of key biogeochemical events, which allowed us to illustrate spatially- and seasonally-dependent shifts in the magnitude of linked biogeochemical parameters. Specifically, we found that a modest reduction in nitrate input was linked to a suppression of spring phytoplankton biomass in seaward Bay regions. This was, in turn, associated with an earlier breakup in hypoxia and decline in late-summer NH4+ accumulation in seaward waters. In contrast, we observed an increase in winter phytoplankton biomass in landward regions, which was associated with elevated early summer hypoxic volumes and NH4+ accumulation. Seasonal shifts in oxygen depletion and NH4+ accumulation are consistent with reduced nitrogen inputs, spatial patterns of chlorophyll-a, and increases in temperature. In addition, these increases have likely elevated rates of organic matter degradation, thus “speeding-up” the typical seasonal cycle. The causes for the recent landward shift in phytoplankton biomass and NH4+ accumulation are less clear; however, these altered patterns are analyzed here and discussed in terms of numerous physical, climatic, and biological changes in the estuary.

Highlights

  • Estuaries are dynamic coastal environments that respond to a variety of external forces, including freshwater and material inputs from surrounding watersheds, as well as annual and seasonal changes in temperature, wind stress, and exchanges with the adjacent coastal ocean

  • Mean seasonal cycles of hypoxic and anoxic volume in Chesapeake Bay shifted over the 1985–2015 period, with higher-than-average early summer (May–June) volumes, but lower-than-average late summer (July–September) volumes in the latter half of the time series (2000–2015) relative to the initial period (1985–1999; Figure 2)

  • No clear change in physical forcing was evident from our analysis of stratification that could have caused the late summer reoxygenation, and previous model simulations have shown a high dependence of hypoxic volume on early summer water-column respiration

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Summary

Introduction

Estuaries are dynamic coastal environments that respond to a variety of external forces, including freshwater and material inputs from surrounding watersheds, as well as annual and seasonal changes in temperature, wind stress, and exchanges with the adjacent coastal ocean. A more complete understanding of the varied responses of estuaries to external inputs and effects is necessary for constraining predictions of future ecosystem states under altered climate patterns and other anthropogenic effects (e.g., nutrient inputs). While many climatic changes and their ecosystem effects may be cyclical, occurring on decadal scales (e.g., NAO, PDO; Ottersen et al, 2001; Cloern et al, 2007), long-term projections of future precipitation and temperature generally suggest gradual increases in the mid-Atlantic region of the United States (Johnson et al, 2016). The extent to which these changes are focused in particular seasons will influence ecosystem responses

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