Is there a geomorphic expression of interbasin groundwater flow in watersheds? Interactions between interbasin groundwater flow, springs, streams, and geomorphology

Frisbee, Marty D.; Tysor, Elizabeth H.; Stewart-Maddox, Noah; Tsinnajinnie, L.; Wilson, John L.; Granger, Darryl E.; Newman, Brent D.

doi:10.1002/2015gl067082

Cited by 28 publications

(41 citation statements)

References 30 publications

(31 reference statements)

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“…If this model is accepted and the hypothesized shallow groundwater endmember is ignored, then we implicitly overlooked the non‐conservative behaviour of Si, and we have also ignored the stream water compositions that do not fall on the EM1–EM2–EM3 projected space (Figure c). As Si is a major weathering product for most sites (White, ; White & Blum, ), and it is a useful tool for understanding subsurface chemical denudation processes (Frisbee, Tolley, & Wilson, ; Frisbee, Phillips, White, Campbell, & Liu, ; Frisbee et al, ), ignoring the non‐conservative behaviour of Si or stream water chemistry observations (especially winter season samples) is problematic. Therefore, the model CM2A is abandoned, and other models with the same mixing space dimension are considered next.…”

Section: Discussionmentioning

confidence: 99%

Hydrologic functioning of the deep critical zone and contributions to streamflow in a high‐elevation catchment: Testing of multiple conceptual models

Dwivedi

Meixner

McIntosh

et al. 2019

Hydrological Processes

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High-elevation mountain catchments are often subject to large climatic and topographic gradients. Therefore, high-density hydrogeochemical observations are needed to understand water sources to streamflow and the temporal and spatial behaviour of flow paths. These sources and flow paths vary seasonally, which dictates short-term storage and the flux of water in the critical zone (CZ) and affect long-term CZ evolution. This study utilizes multiyear observations of chemical compositions and water residence times from the Santa Catalina Mountains Critical Zone Observatory, Tucson, Arizona to develop and evaluate competing conceptual models of seasonal streamflow generation. These models were tested using endmember mixing analysis, baseflow recession analysis, and tritium model "ages" of various catchment water sources. A conceptual model involving four endmembers (precipitation, soil water, shallow, and deep groundwater) provided the best match to observations. On average, precipitation contributes 39-69% (55 ± 16%), soil water contributes 25-56% (41 ± 16%), shallow groundwater contributes 1-5% (3 ± 2%), and deep groundwater contributes~0-3% (1 ± 1%) towards annual streamflow. The mixing space comprised two principal planes formed by (a) precipitation-soil water-deep groundwater (dry and summer monsoon season samples) and (b) precipitation-soil water-shallow groundwater (winter season samples). Groundwater contribution was most important during the wet winter season. During periods of high dynamic groundwater storage and increased hydrologic connectivity (i.e., spring snowmelt), stream water was more geochemically heterogeneous, that is, geochemical heterogeneity of stream water is storage-dependent. Endmember mixing analysis and 3 H model age results indicate that only 1.4 ± 0.3% of the long-term annual precipitation becomes deep CZ groundwater flux that influences long-term deep CZ development through both intercatchment and intracatchment deep groundwater flows.

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Section: Discussionmentioning

confidence: 99%

Hydrologic functioning of the deep critical zone and contributions to streamflow in a high‐elevation catchment: Testing of multiple conceptual models

Dwivedi

Meixner

McIntosh

et al. 2019

Hydrological Processes

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“…If a portion of the streamflow comes from other catchments through groundwater import, then weathering rates would be overestimated, disproportionally so for the same reason. These are vividly demonstrated in Figure 11 by Frisbee et al (2016) and Figure 12 by Genereux et al (2009). Further confusion can be introduced if the hydrologic models erroneously placed the groundwater import or export term into the catchment storage term.…”

Section: Catchment Biogeochemical Export and Critical Zone Evolutionmentioning

confidence: 99%

“…Yellow and blue lines mark cross‐sections shown to the right. (Reprinted with permission from Frisbee et al (). Wiley 2016)…”

Section: Groundwater Export and Import From Catchmentsmentioning

confidence: 99%

“…As mentioned earlier, Stewart‐Maddox et al () and Frisbee et al () integrated data on geology, hydrology (e.g., gaining vs. losing streams, clustering of springs), geomorphology (asymmetry in hillslope and channel profiles), and geochemistry (trends in 87 Sr/ 86 Sr, inverse geochemical modeling of groundwater evolution). In doing so, they “bookended” the intercatchment groundwater transfer, showing its termination at the second catchment in a three‐catchment catena (Figure ).…”

Section: Groundwater Export and Import From Catchmentsmentioning

confidence: 99%

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Are catchments leaky?

Fan

2019

WIREs Water

122

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Catchments, generally understood as the drainage areas of low‐order streams, are often regarded as closed hydrologic entities; that is, precipitation (P) minus evapotranspiration (ET) over a catchment equates stream outflow (Q r). Here, we review evidence that catchments can be leaky due to groundwater outflow or inflow across topographic divides, based on catchment mass balance across a continent and several site‐based studies across the globe. It appears that a catchment is more likely to be leaky with the combination of the following factors: small catchment size, positioned at either the high or low end of a steep regional topographic and climatic gradient, underlain by deep permeable substrates that extend beyond the study catchment, and in drier climate or dry seasons and droughts. Catchment leakage has hydrological, geochemical, and ecological implications. Thus, catchments are best framed as semiclosed hydrologic units perched on top of a larger, regional hydrogeological system with no real boundaries regarding the movement of water and solutes. This article is categorized under: Science of Water > Hydrological Processes Water and Life > Nature of Freshwater Ecosystems

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“…During base flow, headwater streams act as surficial expressions of groundwater conditions, providing observable spatiotemporal information of groundwater storage within catchments (e.g., Bencala et al, 2011;Biswal & Nagesh Kumar, 2013;Godsey & Kirchner, 2014;Kirchner, 2009;Shaw et al, 2017;Whiting & Godsey, 2016). In rain-dominated climates, all stream flow during these dry periods must come from water stored belowground, typically in the form of slowly draining groundwater that is locally sourced from adjacent hillslopes or is derived from regional groundwater systems that may cross local hillslopes or topographic watershed divides (e.g., Broda et al, 2012Broda et al, , 2014Clark et al, 2009;Frisbee et al, 2016;Gleeson & Manning, 2008;McNamara et al, 2011;Payn et al, 2012;Sheets et al, 2015;Tague & Grant, 2004;T oth, 1963;Troch et al, 2003;Welch & Allen, 2012). The hydraulic conductivity, geometry, and volume of this storage source should impact both the persistence and distribution of wetted channels in the dry season.…”

Section: Introductionmentioning

confidence: 99%

Drainage from the Critical Zone: Lithologic Controls on the Persistence and Spatial Extent of Wetted Channels during the Summer Dry Season

Lovill

Hahm

Dietrich

2018

Water Resources Research

154

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In seasonally dry environments, critical zone drainage provides base flow that sustains river ecosystems. The extent of wetted channels and magnitude of base flow throughout the network, however, are rarely documented, and no general theory currently exists enabling the prediction of these key ecosystem properties. We conducted channel surveys in early and late summers of 2012, 2014, and 2015 in four headwater drainage networks (2.8–17.0 km2, in the Franciscan Formation of the Eel River (Northern California)), two of which are underlain by the Coastal Belt (argillite and inter‐bedded sandstone) and two of which are underlain by the Central Belt (sheared argillaceous‐matrix, meta‐sedimentary mélange). In all networks, stationary springs controlled the extent of flow. Though surveyed during a period of multiyear drought, the two adjacent Coastal Belt networks remained flowing throughout late‐summer months, sustained by drainage from groundwater stored in thick weathered bedrock above fresh, impermeable bedrock. Flow magnitudes, however, decreased and surface flows became increasingly discontinuous, largely due to infiltration into thick gravel deposits on the channel bed. Only 23 km away, in the Central Belt mélange, channel flow ceased early in the summer because the thin critical zone (typically <3 m) stored little water. All late‐summer flowing water initiated from deep‐rooted sandstone blocks and terminated a short distance downslope. Our findings suggest that lithology and critical zone development exert primary controls on wetted channel extent. Given similar annual precipitation, nearby watersheds can have dramatically different summer wetted channel networks that result in fundamentally different aquatic ecosystems.

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Is there a geomorphic expression of interbasin groundwater flow in watersheds? Interactions between interbasin groundwater flow, springs, streams, and geomorphology

Cited by 28 publications

References 30 publications

Hydrologic functioning of the deep critical zone and contributions to streamflow in a high‐elevation catchment: Testing of multiple conceptual models

Hydrologic functioning of the deep critical zone and contributions to streamflow in a high‐elevation catchment: Testing of multiple conceptual models

Are catchments leaky?

Drainage from the Critical Zone: Lithologic Controls on the Persistence and Spatial Extent of Wetted Channels during the Summer Dry Season

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