Abstract
Accurate estimates of freshwater flow to the San Francisco Estuary are important in successfully regulating this water body, in protecting its beneficial uses, and in accurately modeling its hydrodynamic and water-quality transport regime. For regulatory purposes, freshwater flow to the estuary is not directly measured; rather, it is estimated from a daily balance of upstream Delta inflows, exports, and in-Delta water use termed the net Delta outflow index (NDOI). Field research in the 1960s indicated that NDOI estimates are biased low in summer–fall and biased high in winter–spring as a result of conflating Delta island evapotranspiration estimates with the sum of ungauged hydrologic interactions between channels and islands referred to as net channel depletions. In this work, we employed a 50-year observed salinity record along with gauged tidal flows and an ensemble of five empirical flow-salinity (X2) models to test whether a seasonal bias in Delta outflow estimates could be inferred. We accomplished this objective by conducting statistical analyses and evaluating whether model skill could be improved through seasonal NDOI flow adjustments. Assuming that model residuals are associated with channel depletion uncertainty, our findings corroborate the 1960s research and suggest that channel depletions are biased low in winter months (i.e., NDOI is biased high) and biased high in late summer and early fall months (i.e., NDOI is biased low). The magnitude of seasonal bias, which can reach 1,000 cfs, is a small percentage of typical winter outflow but represents a significant percentage of typical summer outflow. Our findings were derived from five independently developed models, and are consistent with the physical understanding of water exchanges on the islands. This work provides motivation for improved characterization of these exchanges to improve Delta outflow estimates, particularly during drought periods when water supplies are scarce and must be carefully managed.
Highlights
The Mediterranean climate of California is relatively dry and contributes to periodic shortages among the urban, agricultural, and environmental water-using sectors of the state
We accomplished this latter comparison by comparing observed salinity (X2) with the isohaline position as predicted by a suite of flow-based empirical models (Jassby et al 1995; Monismith et al 2002; MacWilliams et al 2015; Hutton et al 2015; and Monismith 2017) that were consistently recalibrated by Rath et al (2021, this volume)
Seasonal Bias Revealed by Observed Outflow Data As mentioned above, Delta outflow estimates provided by the US Geological Survey (USGS) gauge data and Net Delta Outflow Index (NDOI) water balance are strongly correlated over the full annual range of flow
Summary
The Mediterranean climate of California is relatively dry and contributes to periodic shortages among the urban, agricultural, and environmental water-using sectors of the state. Legislation was enacted (Assembly Bill 1755), which requires the California Department of Water Resources (CDWR) to develop protocols for water data sharing, documentation, quality control, public access, and promotion of open-source platforms and decision-support tools. Compared to other deltaic regions of the world, the Delta is unusual in having formed significantly inland from its ocean outlet It is the entry point of over 90% of the freshwater inflow to San Francisco Bay (Cheng et al 1993) and is drained by a vast 194,000 km watershed, including the high-elevation Sierra Nevada mountain range and the Central Valley (US EPA 2012). River flows and tidal action have deposited sediments in the Delta, the low point of the Central Valley As these sediment deposits covered tules and other plants, thick organic peat soils were formed.
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