Spatial Patterns and Sensitivity of Intermittent Stream Drying to Climate Variability

Moidu, Hana; Obedzinski, Mariska; Carlson, Stephanie M.; Grantham, Theodore E.

doi:10.1029/2021wr030314

Cited by 22 publications

(25 citation statements)

References 77 publications

(93 reference statements)

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“…Because fish are planted in the previous fall and most often experience >50% overwinter mortality (California Sea Grant, 2021b), we could not test whether the total number of outmigrating smolts was lower in drought versus non‐drought years. Nevertheless, we can assume that smolts that do not outmigrate in the spring are unlikely to survive until the rainy season, owing to the extensive stream drying that occurs in tributaries of the Russian River watershed (Moidu et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

Migration in drought: Receding streams contract the seaward migration window of endangered salmon

et al. 2022

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Prolonged migration windows buffer migratory animal populations against uncertainty in resource availability. Understanding how intensifying droughts from climate change influence the migration window is critical for biodiversity conservation in a warming world. We explored how drought affects the seaward migration of endangered coho salmon (Oncorhynchus kisutch) near the southern extent of their range in California, USA. We tracked stream departures of juvenile coho, measuring streamflow and temperature in seven streams over 13 years, spanning a historic drought with extreme dry and warm conditions. Linear mixed effects models indicate that, over the range of observations, a decrease in seasonal streamflow (from 4.5 to 0.5 mm/day seasonal runoff) contracted the migration window by 31% (from 11 to 7 weeks). An increase from 10.2 to 12.8°C in mean seasonal water temperature hastened the migration window by three weeks. Pacific salmon have evolved to synchronize ocean arrival with productive ocean upwelling. However, earlier and shorter migration windows during drought could lead to mismatches, decreasing fitness and population stability. Our study demonstrates that drought‐induced low flows and warming threaten coho salmon in California and suggests that environmental flow protections will be needed to support the seaward migration of Pacific salmon in a changing climate.

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Section: Discussionmentioning

confidence: 99%

Migration in drought: Receding streams contract the seaward migration window of endangered salmon

et al. 2022

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“…Recent work by Vorste et al (2020), however, highlights that some intermittent systems provide reliable habitats for juvenile coho rearing. For example, across the geologically complex Russian River watershed in Sonoma County, California, interannual variation in summer survival was high at some sites, but much more stable at other sites, hinting at the importance of CZ properties in influencing the sensitivity of different systems to interannual variation in rainfall and consequences for salmon survival (e.g., Figure 8; see also Moidu et al, 2021).…”

Section: Juvenile Growth and Summer Survivalmentioning

confidence: 99%

The salmonid and the subsurface: Hillslope storage capacity determines the quality and distribution of fish habitat

et al. 2023

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Water in rivers is delivered via the critical zone (CZ)-the living skin of the Earth, extending from the top of the vegetation canopy through the soil and down to fresh bedrock and the bottom of significantly active groundwater.Consequently, the success of stream-rearing salmonids depends on the structure and resulting water storage and release processes of this zone. Physical processes below the land surface (the subsurface component of the CZ) ultimately determine how landscapes "filter" climate to manifest ecologically significant streamflow and temperature regimes. Subsurface water storage capacity of the CZ has emerged as a key hydrologic variable that integrates many of these subsurface processes, helping to explain flow regimes and terrestrial plant community composition. Here, we investigate how subsurface storage controls flow, temperature, and energetic regimes that matter for salmonids. We illustrate the explanatory power of broadly applicable, storage-based frameworks across a lithological gradient that spans the Eel River watershed of California. Study sites are climatically similar but differ in their geologies and consequent subsurface CZ structure that dictates water storage dynamics, leading to dramatically different hydrographs, temperature, and riparian regimes-with consequences for every aspect of salmonid life history. Lithological controls on the development of key subsurface CZ properties like storage capacity suggest a heretofore unexplored link between salmonids and geology, adding to a rich literature that highlights various fluvial and geomorphic influences on salmonid diversity and distribution. Rapidly advancing methods for estimating and observing subsurface water storage dynamics at large scales present new opportunities for more clearly identifying landscape features that constrain the distributions and abundances of organisms, including salmonids, at watershed scales.

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“…As hydrological regimes shift in response to increasing anthropogenic pressures and a changing climate, so too will the wetted extent of channel networks (Lapides et al, 2021), with consequences for food webs, sedimentation, riverine nutrient cycling, habitat extent/quality, and other ecological processes (Bernal et al, 2004;Hwan & Carlson, 2016;Sabo et al, 2010;Larned et al, 2010;Arthington et al, 2005). A remote-sensing based framework for detecting the absence or presence of water in (often difficult-to-access) headwater stream networks would contribute to ongoing efforts to address this significant challenge in watershed management (Moidu et al, 2021).…”

Section: L-q Relations and The Persistence Of Wetted Channel Extentmentioning

confidence: 99%

“…However, these surveys are limited in their spatiotemporal coverage: less than 0.0001% of Earth's ice-free land area has been repeatedly mapped (Lapides et al, 2021), underscoring the status of headwater stream networks as aqua incognita (Bishop et al, 2008). Sparse observations have limited exploration of the physical controls on channel growth and contraction (Moidu et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Harnessing hyperspectral imagery to map surface water presence and hyporheic flow properties of headwater stream networks

Dralle¹,

Lapides²,

Rempe³

et al. 2022

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Growth and contraction of headwater stream networks determine the extent and quality of ecologically critical habitat, and open a window into the storage dynamics of catchments. A fundamental challenge is observation of the process itself: wetted channel extent is highly dynamic in space and time, with the length of wetted channel sometimes varying by orders of magnitude over the course of a single storm event in headwater catchments. To date, observational datasets are produced from boots-on-the-ground campaigns, drone imaging, or flow presence sensors, which are often laborious and limited in their spatial and temporal extents. Here, we evaluate high-resolution, multi-band satellite imagery as a means to detect wetted channel extent via machine learning methods trained using existing wetted channel extent surveys. Even where channel features are smaller than the spatial resolution of the imagery, the absence or presence of surface water may nevertheless be imprinted upon the spectral signature of an individual pixel. We leverage existing wetted channel extent surveys at two oak savanna catchments in northern California with minimal riparian canopy cover and highly dynamic wetted channel extent due to small subsurface water storage capacity and saturation overland flow. We train a random forest model on high-resolution ($\sim$5 m pixel) RapidEye satellite imagery captured contemporaneously with the existing surveys. Withheld test data indicates prediction accuracy of wet vs. dry channel extent is $>$91\%. This predictive ability is used to produce length-discharge (L-Q) relations and to calculate spatially distributed estimates of channel hyporheic flow capacity and exchange. A sharp break in hyporheic flow properties occurs at the transition from main stem channels to lower order tributaries, resulting in a stepped L-Q relationship that cannot be captured by traditionally used power law models. Remotely sensed imagery is a powerful tool for producing wetted channel maps at high spatial resolution ($\sim$10 m in this study to channels with $>$ 0.01 km$^2$ contributing area).

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Spatial Patterns and Sensitivity of Intermittent Stream Drying to Climate Variability

Cited by 22 publications

References 77 publications

Migration in drought: Receding streams contract the seaward migration window of endangered salmon

Migration in drought: Receding streams contract the seaward migration window of endangered salmon

The salmonid and the subsurface: Hillslope storage capacity determines the quality and distribution of fish habitat

Harnessing hyperspectral imagery to map surface water presence and hyporheic flow properties of headwater stream networks

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