Spruce Beetle Outbreak Increases Streamflow From Snow‐Dominated Basins in Southwest Colorado, USA

Manning, Aidan; Harpold, Adrian A.; Csank, A. Z.

doi:10.1029/2021wr029964

Cited by 10 publications

(8 citation statements)

References 81 publications

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“…We speculate that precipitation, temperature, and catchment size may regulate near-universal hydrological processes that are responsible for the highly compressible components of streamflow regime (those captured by the 7 PCA metrics) (Giano, 2021;N. LeRoy Poff et al, 1997), and that the more complicated ecohydrological interactions introduced by the myriad possible land use regimes and geological factors are responsible for streamflow properties that were harder to identify with PCA analysis (Bladon et al, 2014;Manning et al, 2022;Tague & Grant, 2004;Wu et al, 2021)-though we note that land use is likely correlated with climatic and geological factors. Said differently, our results imply that a simple, emergent physics may exist at the catchment scale, where a handful of mean catchment properties accurately predict flashiness, timing, and volume of flow at the basin's outlet, to the extent that biological interactions remain simple (Sposito, 2017;Zhou et al, 2015).…”

Section: Streamflowmentioning

confidence: 89%

“…We further suggest that as biogeochemical datasets increase in temporal and spatial scales, data-driven descriptors based on low-dimensional structure are key for several reasons: 1) they provide sanity checks of intuitive notions or concepts common in sub-disciplines that are otherwise quantitatively unfalsifiable (Kipper, 2021). For example, in hydrology the notions of "semi-arid watersheds" and "snow-driven watersheds" are commonly employed in the literature (Arheimer et al, 2017;Cosh et al, 2008;Manning et al, 2022;Poon & Kinoshita, 2018). We suggest that these intuitive concepts represent informal, expert-driven versions of dimension reduction (Bates, 2020;Wolff, 2019).…”

Section: Low-dimensional Structure In Streamflow Timeseriesmentioning

confidence: 99%

See 1 more Smart Citation

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

Brown

Fulerton

Kopp³

et al. 2022

Preprint

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River flows change on timescales ranging from minutes to millennia. These variations influence fundamental functions of ecosystems, including biogeochemical fluxes, aquatic habitat, and human society. Efforts to describe temporal variation in river flow—i.e., flow regime—have resulted in hundreds of unique descriptors, complicating interpretation and identification of global drivers of flow dynamics. Here, we used a cross-disciplinary analytical approach to investigate two related questions: 1. Is there a low-dimensional structure that can be used to simplify descriptions of streamflow regime? 2. What catchment characteristics are most associated with that structure? Using a global database of daily river discharge from 1988-2016 for 3,120 stations, we calculated 189 traditional flow metrics, which we compared to the results of a wavelet analysis. Both quantification techniques independently revealed that streamflow data contain substantial low-dimensional structure that correlates closely with a small number of catchment characteristics. This structure provides a framework for understanding fundamental controls of river flow variability across multiple timescales. Climate was the most important variable across all timescales, especially those lasting several weeks, and likely contributes as much as dams in controlling flow regime. Catchment area was critical for timescales lasting several days, as was human impact for timescales lasting several years. In addition, both methods suggested that streamflow data also contain high-dimensional structure that is harder to predict from a small number of catchment characteristics (i.e. is dependent on land use, soil structure, etc.), and which accounts for the difficulty of producing simple hydrological models that generalize well.

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Section: Streamflowmentioning

confidence: 89%

Section: Low-dimensional Structure In Streamflow Timeseriesmentioning

confidence: 99%

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

Brown

Fulerton

Kopp³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…And while individual land use characteristics were not particularly important in isolation, machine learning models consistently ranked this group to be as important as catchment area for predicting variability in flow at all timescales longer than a few months (Figure 10). We speculate that precipitation, temperature, and catchment size may regulate near‐universal hydrological processes that are responsible for the highly compressible components of streamflow regime (those captured by the seven PCA metrics; Giano, 2021; Poff et al., 1997), and that the more complicated ecohydrological interactions introduced by the myriad possible land use regimes and geological factors are responsible for the streamflow properties that were harder to identify with PCA analysis (Bladon et al., 2014; Manning et al., 2022; Tague & Grant, 2004; S. Wu et al., 2021), corroborating the need for a large number of non‐generalizable parameters that frequently occurs in modeling scenarios (Horton et al., 2022). Said differently, our results imply that a simple, emergent physics may exist at the catchment scale, where a handful of mean catchment properties accurately predict flashiness, timing, and volume of flow at the basin's outlet, to the extent that biological interactions remain simple (Sposito, 2017; Zhou et al., 2015).…”

Section: Discussionmentioning

confidence: 99%

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

Brown

Fulerton

Kopp³

et al. 2023

Water Resources Research

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River flow drives the structure and function of aquatic systems on sub-daily to decadal timescales, and sculpts landscapes on geological timescales from months to millennia (Fisher et al., 1998;Pinay et al., 2018;Tucker & Hancock, 2010). For people, variability in river flow regulates access to freshwater, with extreme flow events such as floods and droughts imposing immense personal and societal costs (

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“…This sub-alpine altitudinal band accounts for 25% of the total area of the European Alps and is thus more widespread in terms of area than the alpine (>2000m altitude) altitudinal band (15%). It is in these sub-alpine environments, that forest and water management strategies are needed to counteract the mentioned climate change impacts and to preserve a functioning eco-hydrologic system (Barnhart et al, 2016;Manning et al, 2022;Niittynen et al, 2018). Snow cover and its spatio-temporal variability are controlled by vegetation, topography and meteorology (e.g.…”

Section: Introductionmentioning

confidence: 99%

Spatio-temporal Snow Variability in a Sub-Alpine Forest predicted by Machine Learning and UAV-based LiDAR Snow Depth Maps

Geissler

Rathmann

Weiler

2023

Preprint

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Snow interacts with its environment in many ways, is constantly changing with time, and thus has a highly heterogeneous spatial and temporal variability. Therefore, modeling snow variability is difficult, especially when additional components such as vegetation add complexity. To increase our understanding of the spatio-temporal variability of snow and to validate snow models, we need reliable observation data at similar spatial and temporal scales. For these purposes, airborne LiDAR surveys or time series derived from snow sensors on the point scale are commonly used. However, these are limited either to one point in space or in time. We present a new, extensive dataset of snow variability in a sub-alpine forest in the Alptal, Switzerland. The core dataset consists of a dense sensor network, repeated high-resolution LiDAR data acquired using a fixed-wing UAV, and manual snow depth and snow density measurements. Using machine learning algorithms, we determine four distinct spatial clusters of similar snow depth dynamics. These clusters are characterized and further used to derive daily snow depth and snow water equivalent (SWE) maps. The results underline the complex relation of topography and canopy cover towards snow accumulation and ablation. The derived products are the first to our knowledge that provide daily, high-resolution snow depth and SWE based almost exclusively on field data. They are therefore ideally suited for the validation of distributed snow models. Our approach can be applied to other project areas and improve our understanding of the spatio-temporal variability of snow in forested environments.

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Spruce Beetle Outbreak Increases Streamflow From Snow‐Dominated Basins in Southwest Colorado, USA

Cited by 10 publications

References 81 publications

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

The Music of Rivers: The Mathematics of Waves Reveals Global Structure and Drivers of Streamflow Regime

Spatio-temporal Snow Variability in a Sub-Alpine Forest predicted by Machine Learning and UAV-based LiDAR Snow Depth Maps

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