Salmon of California’s Central Valley are culturally and ecologically valuable but are subject to numerous stressors.
This project used sociological and ecological methods to address salmonid recovery in the Central Valley in an inclusive and collaborative way. The research team identified a suite of implementable and impactful actions that will advance the recovery of Central Valley salmon and steelhead. The approach promoted broad buy-in for these preferred actions by making trade-offs transparent and balancing participants’ diverse values, perspectives, and priorities.
Spring-run Chinook salmon (Oncorhynchus tshawytscha) are a high-priority species under the Endangered Species Act due to their risk of extinction. However, understanding the factors affecting their populations is difficult when monitoring focuses only on returning adult spawners. This limited view overlooks critical life stages. To address this gap, the project aimed to estimate the number of juvenile salmon leaving the Delta at Chipps Island. Monitoring salmon throughout their entire life cycle is essential for identifying the key factors influencing their survival and reproduction.
There is a need from both scientists and managers for accurate data to make informed decisions about salmon protection and conservation. The Department of Water Resources (DWR) mandates that juvenile production estimates for spring-run salmon be included in their incidental take permit, which is necessary for the continued operation of the State Water Project. A method to estimate juvenile abundance of spring-run salmon leaving the Delta (at Chipps Island) did not yet exist.
To develop these annual estimates, researchers built on previous studies and incorporated new genetic data into updated models. This approach maximized the use of available information and the latest genetic research to improve the protection and understanding of these threatened fish.
This project examined cold water storage and regulation in Shasta Lake through the Shasta Dam Temperature Control Device (TCD). The TCD is a 300-foot structure with multiple gate openings, allowing water from different depths - and thus different temperatures - to be selectively released to manage water temperature in the river downstream. River water temperature is managed to support the imperiled Chinook salmon, a species of fish that is native to California. This capability is becoming increasingly important because low water years generally mean warmer river water temperatures that compromise habitat suitability for different species. In particular, cold pool management is essential for downstream spawning and rearing habitat for winter-run Chinook salmon that rely on cooler water temperatures to survive and reproduce. When the water is too warm, oxygen availability is limited for Chinook salmon and their eggs, which contributes to their mortality. Although the TCD allows reservoir managers to control water release and downstream water temperature, flow contributions into the TCD under day-to-day operations for different gate openings, operations, and thermal conditions within the reservoir are largely unquantified. Further complicating temperature management, TCD leakage (whether within the structure itself or through malfunctioning gates) needs to be better quantified in location and magnitude. This information will improve operational strategies for cold water performance especially during summer and fall months to manage cold water supply for downstream Chinook salmon habitat.
