Stochastic in Space and Time: 1. Characterizing Orographic Gradients in Mean Runoff and Daily Runoff Variability

Mountain topography alters the phase, amount, and spatial distribution of precipitation. Past efforts focused on how orographic precipitation can alter spatial patterns in mean runoff, with less emphasis on how time‐varying runoff statistics may also vary with topography. Given the importance of the...

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Bibliographic Details
Published in:Journal of geophysical research. Earth surface 2024-03, Vol.129 (3), p.n/a
Main Authors: Forte, A. M., Rossi, M. W.
Format: Article
Language:English
Subjects:
climate‐tectonics
Daily
Daily runoff
Empirical analysis
Fluid dynamics
fluvial erosion
Hydrologic data
Mountains
Numerical experiments
Orographic effects
Orographic precipitation
orography
Physical simulation
Precipitation
Rain
Random variables
River discharge
River flow
River runoff
Rivers
Runoff
runoff variability
Shadows
Snowmelt
Spatial distribution
Statistical analysis
stochastic threshold incision model
Stochasticity
Topography
Uplift
Variability
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Summary:Mountain topography alters the phase, amount, and spatial distribution of precipitation. Past efforts focused on how orographic precipitation can alter spatial patterns in mean runoff, with less emphasis on how time‐varying runoff statistics may also vary with topography. Given the importance of the magnitude and frequency of runoff events to fluvial erosion, we evaluated whether orographic patterns in mean runoff and daily runoff variability can be constrained using the global WaterGAP3 water model data. Model runoff data are validated against observational data in the contiguous United States, showing agreement with mean runoff in all settings and daily runoff variability in settings where rainfall‐runoff predominates. In snowmelt‐influenced settings, runoff variability is overestimated by the water model data. Cognizant of these limitations, we use the water model data to develop relationships between mean runoff and daily runoff variability and how these are mediated by snowmelt fraction in mountain topography globally. A global analysis of topographic controls on hydroclimatic variables using a random forest model was ambiguous. Instead, relationships between topography and runoff parameters are better assessed at the mountain range scale. Rulesets linking topography to mean runoff and snowmelt fraction are developed for three mid‐latitude mountain landscapes—British Columbia, European Alps, and Greater Caucasus. Increasing topographic elevation and relief together leads to higher mean runoff and lower runoff variability due to the increasing contribution of snowmelt. The three sets of empirical relationships developed here serve as the basis for a suite of numerical experiments in our companion manuscript (Part 2, Forte & Rossi, 2024a, https://doi.org.10.1002/2023JF007327). Plain Language Summary It has long been understood that mountain ranges can have profound influences on the location and intensity of precipitation, for example, through the formation of rain shadows. Less clear is how these “orographic effects” are reflected in the details of river runoff, specifically how much runoff varies from day‐to‐day. Understanding this variability of runoff is important as differences in variability directly influence how rivers respond to changes in rock uplift rate. Here, we use results from a global water model integrated with topography data to explore how runoff variability is related to topography in high relief landscapes. Consistent with prior wor
ISSN:2169-9003
2169-9011
DOI:10.1029/2023JF007326