Long-term time-scale bonds between discharge regime and catchment specific landscape traits in the Spanish Pyrenees

Juez, Carmelo; Nadal‐Romero, Estela

doi:10.1016/j.envres.2020.110158

Cited by 8 publications

(6 citation statements)

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“…To achieve the above goal we use the method of wavelet transformation because of its ability to capture processes variability at multiple time‐scales (Torrence & Compo, 1998). The wavelet transform has been successfully applied in the past to a hydro‐climatic time‐series (Segele et al., 2009; Webster & Hoyos, 2004) and to discharge‐precipitation time‐series (Carey et al., 2013; Juez & Nadal‐Romero, 2020a,2020b) to determine periodicities and trends. We use the wavelet transform instead of other temporal analysis techniques such as Fourier spectral analysis (processes are identified by periodicity, e.g., L. C. Smith et al., 1998) or multi‐scale entropy analysis (processes are identified by their degree of complexity or randomness, e.g., Y. Wang et al., 2018) because of their favorable strengths: (a) wavelet transform can identify processes in both time and periodicity in the non‐stationary time‐series (contrary to Fourier spectral analysis), and (b) wavelet transform allows to localize dominant time‐scales within the complete temporal spectrum, ultimately identifying the variability of each time‐scale throughout the study period (contrary to Fourier spectral analysis and entropy analysis).…”

Section: Introductionmentioning

confidence: 99%

“…To achieve the above goal we use the method of wavelet transformation because of its ability to capture processes variability at multiple time-scales (Torrence & Compo, 1998). The wavelet transform has been successfully applied in the past to a hydro-climatic time-series (Segele et al, 2009;Webster & Hoyos, 2004) and to discharge-precipitation time-series (Carey et al, 2013;Juez & Nadal-Romero, 2020a,2020b to determine periodicities and trends. We use the wavelet transform instead of other temporal analysis techniques such as Fourier spectral analysis (processes are identified by periodicity, e.g., L. C. Smith et al, 1998) or multi-scale entropy analysis (processes are identified by their degree of complexity or randomness, e.g., Y.…”

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confidence: 99%

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Intraseasonal‐to‐Interannual Analysis of Discharge and Suspended Sediment Concentration Time‐Series of the Upper Changjiang (Yangtze River)

Juez

Garijo

Hassan

et al. 2021

Water Resources Research

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 Distinct time-scales of discharge and SSC are identified and related qualitatively to seasonal, annual, and short (1.1-5 year) and long-term (5.5-20 year) variability  Similar dominant time-scales of variability for discharge and SSC are identified in the Upper Changjiang for a 50-years study period  Bi-modal seasonal climatic pattern influence short-term time-scales whereas high magnitude flow events control intra-annual time-scales Accepted ArticleThis article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process, which may lead to differences between this version and the Version of Record. Please cite this article as

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Intraseasonal‐to‐Interannual Analysis of Discharge and Suspended Sediment Concentration Time‐Series of the Upper Changjiang (Yangtze River)

Juez

Garijo

Hassan

et al. 2021

Water Resources Research

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“…The various open research pathways also include the simultaneous consideration of the spatial proximity of the stations and time series features for obtaining predictions, as well as the utilization of additional time series features from the stochastic (statistical) hydrology and data science fields, and even the utilization of the concept of massive feature extraction [24,25,27,29] from the latter of the aforementioned fields. In fact, although this work already covers a larger variety and a larger number of time series features than usual in stochastic hydrology, many more time series features are available (see, e.g., the ones investigated by Papacharalampous et al [34,35]; Hamed [50]; Montanari [51]; Ledvinka [52]; Ledvinka and Lamacova [53]; Juez and Nadal-Romero [54,55]) and could be useful in streamflow regionalization settings, given also the generally acknowledged significance of finding new informative predictors for obtaining improved predictions.…”

Section: Discussionmentioning

confidence: 99%

Time Series Features for Supporting Hydrometeorological Explorations and Predictions in Ungauged Locations Using Large Datasets

Papacharalampous

Tyralis

2022

Water

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Regression-based frameworks for streamflow regionalization are built around catchment attributes that traditionally originate from catchment hydrology, flood frequency analysis and their interplay. In this work, we deviated from this traditional path by formulating and extensively investigating the first regression-based streamflow regionalization frameworks that largely emerge from general-purpose time series features for data science and, more precisely, from a large variety of such features. We focused on 28 features that included (partial) autocorrelation, entropy, temporal variation, seasonality, trend, lumpiness, stability, nonlinearity, linearity, spikiness, curvature and others. We estimated these features for daily temperature, precipitation and streamflow time series from 511 catchments and then merged them within regionalization contexts with traditional topographic, land cover, soil and geologic attributes. Precipitation and temperature features (e.g., the spectral entropy, seasonality strength and lag-1 autocorrelation of the precipitation time series, and the stability and trend strength of the temperature time series) were found to be useful predictors of many streamflow features. The same applies to traditional attributes such as the catchment mean elevation. Relationships between predictor and dependent variables were also revealed, while the spectral entropy, the seasonality strength and several autocorrelation features of the streamflow time series were found to be more regionalizable than others.

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“…The Yesa reservoir was built for irrigation purposes, and the draining catchment underwent a process of re‐vegetation for the last decades (García‐Ruiz et al., 2015 ). We make use of robust statistical tool such as the wavelet transform method, which is able to distinguish different time‐scales of variability and localize changes in the modes of variability within time‐series (Carey et al., 2013 ; Juez & Nadal‐Romero, 2020 , 2021 ; Juez et al., 2021 ; Labat et al., 2005 ; Pérez‐Ciria et al., 2019 ; Restrepo et al., 2014 ). This is an important step forward in identifying changing patterns at different and non‐similar time‐scales, enabling explaining the causes of observed changes and understanding their implications (Zhang et al., 2011 ).…”

Section: Introductionmentioning

confidence: 99%

Six Decades of Hindsight Into Yesa Reservoir (Central Spanish Pyrenees): River Flow Dwindles as Vegetation Cover Increases and Mediterranean Atmospheric Dynamics Take Control

Juez

Garijo

Vicente‐Serrano

et al. 2023

Water Resources Research

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River discharge has experienced diverse changes in the last decades due to modification of hydrological patterns, anthropogenic intervention, re‐vegetation or annual and interannual climatic and atmospheric fluctuations. Assessing the recent changes in river discharge and understanding the main drivers of these changes is thus extremely important from theoretical and applied points of view. More specifically, here we want to draw attention toward the impacts of streamflow changes on reservoir storage and operation. We describe the hydrological dynamics of the Yesa reservoir draining catchment, located in the central Spanish Pyrenees, and characterize the reservoir operation modes over the last 60 years (1956–2020). We analyze concurrent climatic (precipitation, air temperature, drought index), atmospheric mechanisms, land cover (Normalized Different Vegetation Index) and discharge (inlet and outlet of Yesa reservoir) time‐series. By using the wavelet transform methodology, we detect historical breakpoints in the hydrological dynamics at different time‐scales. Distinctive periods are thus identified. More regular seasonal flows characterized the catchment's dynamics during the first decades of the study period, while the last decades were characterized by a high inter‐annual variability. These changes are primarily attributed to the natural re‐vegetation process that the catchment experienced. Furthermore, we related changes in atmospheric circulation with a decline of the long‐term discharge temporal features. This research contributes to the understanding of long‐term river discharge changes and helps to improve the reservoir management practices.

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Long-term time-scale bonds between discharge regime and catchment specific landscape traits in the Spanish Pyrenees

Cited by 8 publications

References 50 publications

Intraseasonal‐to‐Interannual Analysis of Discharge and Suspended Sediment Concentration Time‐Series of the Upper Changjiang (Yangtze River)

Intraseasonal‐to‐Interannual Analysis of Discharge and Suspended Sediment Concentration Time‐Series of the Upper Changjiang (Yangtze River)

Time Series Features for Supporting Hydrometeorological Explorations and Predictions in Ungauged Locations Using Large Datasets

Six Decades of Hindsight Into Yesa Reservoir (Central Spanish Pyrenees): River Flow Dwindles as Vegetation Cover Increases and Mediterranean Atmospheric Dynamics Take Control

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