Scaling frequency of channel‐forming flows in snowmelt‐dominated streams

Segura, Catalina; Pitlick, John

doi:10.1029/2009wr008336

Cited by 29 publications

(27 citation statements)

References 51 publications

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“…Q brk also increases with basin area A (Fig. 3b) as was shown by Segura and Pitlick (2010) who describe F Q = f(Q) and Q brk by broken power law functions.…”

Section: Revised Computation Of Flow Frequency Distributionssupporting

confidence: 52%

“…Differences in Q eff by a few flow bins are attributable to irregularities in the flow frequency data. Results obtained for Q eff in this study are also expected to be unchanged if F Q = f(Q) is expressed by a broken power law function (Segura and Pitlick, 2010).…”

Section: Effects Of Flow Frequency Distribution Typementioning

confidence: 89%

“…Flow frequency curves F Q = f(Q) are similar among high elevation Rocky Mountain streams with snowmelt regimes (see also Torizzo and Pitlick, 2004;Segura and Pitlick, 2010). The majority of flows (on average 60-80%) fall into the first discharge bin, and approximately 5-10% into the second.…”

Section: Revised Computation Of Flow Frequency Distributionsmentioning

confidence: 93%

“…Using 35 bins as opposed to 20 or 50 is a compromise between broad flow classes that result from 20 bins, which might better represent high flows, and narrow flow classes that result from 50 bins and might define the Q eff more tightly. Using 35 rather than 50 bins (Segura and Pitlick, 2010) also helps minimizing the number of empty flow bins that may occur adjacent to bins containing the largest flows. The number of mean daily flows per bin were counted and expressed as a percentage of N. For a bin with no data, its zero percentage was averaged with the percentage flow frequency of a neighboring non-zero bin, and that percentage value was assigned to both bins.…”

Section: Revised Computation Of Flow Frequency Distributionsmentioning

confidence: 98%

See 3 more Smart Citations

Effective discharge in Rocky Mountain headwater streams

Bunte

Abt

Swingle³

et al. 2014

Journal of Hydrology

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“…Q brk also increases with basin area A (Fig. 3b) as was shown by Segura and Pitlick (2010) who describe F Q = f(Q) and Q brk by broken power law functions.…”

Section: Revised Computation Of Flow Frequency Distributionssupporting

confidence: 52%

Section: Effects Of Flow Frequency Distribution Typementioning

confidence: 89%

Section: Revised Computation Of Flow Frequency Distributionsmentioning

confidence: 93%

Section: Revised Computation Of Flow Frequency Distributionsmentioning

confidence: 98%

See 2 more Smart Citations

Effective discharge in Rocky Mountain headwater streams

Bunte

Abt

Swingle³

et al. 2014

Journal of Hydrology

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“…The selection was achieved using a greedyheuristic search process, which searches for a global optimal solution by finding locally optimal solutions. The selection of DA is consistent with results of other studies that demonstrated the relevance of DA as a major hydrologic scaling parameter, especially for peak and annual flows (e.g., Gupta et al, 1994;Vogel and Sankarasubramanian, 2000;Ogden and Dawdy, 2003;Furey and Gupta, 2005;Segura and Pitlick, 2010). The drainage area, which controls the scale of exchange and interaction between climatic and watershed processes, was selected for all 19 percentiles; the HSI, which is a measure of the control of water movement through the soil matrix (drainage potential), was selected for 10 of the 19 percentiles; and the RF1, which is a measure of extreme climatic events, was selected for 7 of the 19 percentiles.…”

Section: Journal Of the American Water Resources Associationsupporting

confidence: 89%

Estimation of Daily Streamflow of Southeastern Coastal Plain Watersheds by Combining Estimated Magnitude and Sequence

Ssegane

Amatya

Tollner

et al. 2013

J American Water Resour Assoc

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Commonly used methods to predict streamflow at ungauged watersheds implicitly predict streamflow magnitude and temporal sequence concurrently. An alternative approach that has not been fully explored is the conceptualization of streamflow as a composite of two separable components of magnitude and sequence, where each component is estimated separately and then combined. Magnitude is modeled using the flow duration curve (FDC), whereas sequence is modeled by transferring streamflow sequence of gauged watershed(s). This study tests the applicability of the approach on watersheds ranging in size from about 25‐7,226 km2 in Southeastern Coastal Plain (U.S.) with substantial surface storage of wetlands. A 19‐point regionalized FDC is developed to estimate streamflow magnitude using the three most selected variables (drainage area, hydrologic soil index, and maximum 24‐h precipitation with a recurrence interval of 100 years) by a greedy‐heuristic search process. The results of validation on four watersheds (Trent River, North Carolina: 02092500; Satilla River, Georgia: 02226500; Black River, South Carolina: 02136000; and Coosawhatchie River, South Carolina: 02176500) yielded Nash‐Sutcliffe efficiency values of 0.86‐0.98 for the predicted magnitude and 0.09‐0.84 for the predicted daily streamflow over a simulation period of 1960‐2010. The prediction accuracy of the method on two headwater watersheds at Santee Experimental Forest in coastal South Carolina was weak, but comparable to simulations by MIKE‐SHE.

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Sediment supply and channel morphology in mountain river systems: 1. Relative importance of lithology, topography, and climate

Mueller

Pitlick

2013

J. Geophys. Res. Earth Surf.

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115

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[1] Quantifying landscape-scale variations in sediment supply to streams and rivers is fundamental to our understanding of both denudational processes and stream channel morpho-dynamics. Previous studies have linked a variety of sediment-supply proxies to climatic, topographic, or geologic factors, but few have connected these directly to the characteristics of fluvial systems draining these landscapes. Here we correlate landscape controls on sediment supply to observed sedimentology and channel patterns through direct measurements of water and sediment fluxes in over 80 drainage basins ranging in area from 1.4 to 35,000 km 2 in the northern Rocky Mountains, USA. These data show that the relative sediment supply, defined by the bankfull sediment concentration, is dominated by basin lithology, while exhibiting little correlation to factors such as relief, mean basin slope, and drainage density. Bankfull sediment concentrations (bed load and suspended load) increase as much as 100-fold as basin lithology becomes dominated by softer sedimentary and volcanic rocks, relative to basins with more resistant lithologies. As bed load concentrations increase, stream beds become less armored, and bed load grain size coarsens. At very high sediment concentrations, bed surface, subsurface, and bed load grain sizes converge and a transition from single-thread to to braided channel patterns is commonly observed.Citation: Mueller, E. R., and J. Pitlick (2013), Sediment supply and channel morphology in mountain river systems: 1. Relative importance of lithology, topography, and climate,

show abstract

Scaling frequency of channel‐forming flows in snowmelt‐dominated streams

Cited by 29 publications

References 51 publications

Effective discharge in Rocky Mountain headwater streams

Effective discharge in Rocky Mountain headwater streams

Estimation of Daily Streamflow of Southeastern Coastal Plain Watersheds by Combining Estimated Magnitude and Sequence

Sediment supply and channel morphology in mountain river systems: 1. Relative importance of lithology, topography, and climate

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