Determining Hydrological Variability Using a Multi-Catchment Model Approach for the Western Cape, South Africa

Watson, Andrew B.; Midgley, Guy F.; Künne, Annika; Kralisch, Sven; Helmschrot, Jörg

doi:10.3390/su132414058

Cited by 10 publications

(10 citation statements)

References 62 publications

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“…The CFM may have also played a causal role in other factors which influence the phylogeographic structure of taxa, such as drainage systems, climatic patterns and vegetation types. The CFM syntaxis zone represents the interface between western and southern flowing drainage systems, serving to delineate the Eerste and Berg River catchment areas in the west, and the Breede and Bot River catchments to the southeast (Watson et al, 2021 ). Price et al ( 2010 ) highlighted the significant impact which watersheds and catchments can play in cladogenesis even in the absence of geographic features as dramatic as the CFM, and high mountain streams have been frequently shown to demonstrate high levels of species richness in invertebrates, often with distinct biota in discrete mountain catchments (Daniels, 2003 ; Gouws et al, 2004 , 2010 ; Stewart, 1992 ; Wishart & Hughes, 2001 ).…”

Section: Discussionmentioning

confidence: 99%

Between the Cape Fold Mountains and the deep blue sea: Comparative phylogeography of selected codistributed ectotherms reveals asynchronous cladogenesis

Myburgh

Daniels

2022

Evolutionary Applications

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We compare the phylogeographic structure of 13 codistributed ectotherms including four reptiles (a snake, a legless skink and two tortoise species) and nine invertebrates (six freshwater crabs and three velvet worm species) to test the presence of congruent evolutionary histories. Phylogenies were estimated and dated using maximum likelihood and Bayesian methods with combined mitochondrial and nuclear DNA sequence datasets. All taxa demonstrated a marked east/west phylogeographic division, separated by the Cape Fold Mountain range. Phylogeographic concordance factors were calculated to assess the degree of evolutionary congruence among the study species and generally supported a shared pattern of diversification along the east/west longitudinal axis. Testing simultaneous divergence between the eastern and western phylogeographic regions indicated pseudocongruent evolutionary histories among the study taxa, with at least three separate divergence events throughout the Mio/Plio/Pleistocene epochs. Climatic refugia were identified for each species using climatic niche modelling, demonstrating taxon‐specific responses to climatic fluctuations. Climate and the Cape Fold Mountain barrier explained the highest proportion of genetic diversity in all taxa, while climate was the most significant individual abiotic variable. This study highlights the complex interactions between the evolutionary history of fauna, the Cape Fold Mountains and past climatic oscillations during the Mio/Plio/Pleistocene. The congruent east/west phylogeographic division observed in all taxa lends support to the conclusion that the longitudinal climatic gradient within the Greater Cape Floristic Region, mediated in part by the barrier to dispersal posed by the Cape Fold Mountains, plays a major role in lineage diversification and population differentiation.

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Section: Discussionmentioning

confidence: 99%

Between the Cape Fold Mountains and the deep blue sea: Comparative phylogeography of selected codistributed ectotherms reveals asynchronous cladogenesis

Myburgh

Daniels

2022

Evolutionary Applications

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“…Bias correction can be difficult in environments where extreme isotope signatures are the most important and drive the hydrological response, such as for the Western Cape (van Rooyen et al, 2021;Watson, Eilers, & Miller, 2020), but various quantile mapping approaches (Gudmundsson et al, 2012) are available and can be used under different climatic conditions. As the JAMS/J2000 has a modular component structure these new developments could support a wider use of isotope-enabled models, given that the JAMS/J2000 has already been applied across many environments and climates (Fink et al, 2007(Fink et al, , 2017Künne et al, 2019;Meinhardt et al, 2018;Nepal et al, 2021;Watson et al, 2021).…”

Section: Isotope Mixing Considering Data Scarcitymentioning

confidence: 99%

“…Conceptual rainfall‐runoff models can use the streamflow signal to separate the hydrograph into proportions of flow from surface runoff, interflow and baseflow (Jakeman & Hornberger, 1993; Krause, 2001; Willems, 2009). However, as most conceptual model calibrations are usually solely dependent on the streamflow signal, background noise, such as reservoir release and irrigation withdrawals amongst others, can influence model hydrograph separation (Payan et al, 2008; Watson et al, 2021; Xue et al, 2014). Understanding the proportion of surface runoff, interflow and baseflow, which provides insight into crucial hydrological processes such as infiltration, evapotranspiration/root water uptake and groundwater recharge/deep percolation, is important to constrain and predict hydrological change.…”

Section: Introductionmentioning

confidence: 99%

“…The Berg River catchment has recently been subject to an intense drought (2015)(2016)(2017)(2018), and future climate adaptation measures hinge on the ability to accurately simulate current and future hydrological flows. The approach investigated the potential of reducing the model parameter uncertainty of previous studies (Watson et al, 2021;Watson, Kralisch, et al, 2020;Watson, Miller, Künne, & Kralisch, 2022) and whether more robust model parameters could be identified for modelling under enhanced climate variability outlined by Watson, Midgley, Ray, et al, 2022. Furthermore, the catchment has shown recent changes in average hydrological flows (Watson, Miller, Künne, & Kralisch, 2022), as a response to changes in the upper Berg River, and the J2000iso was used to validate these changes.…”

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confidence: 99%

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Towards the development of an isotope‐enabled rainfall‐runoff model: Improving the ability to capture hydrological and anthropogenic change

Watson

Vystavna

Kralisch

et al. 2023

Hydrological Processes

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Global hydrological alterations are being driven by climate change. However, while modelling tools have been instrumental in identifying these changes, their calibration is often dependent solely on streamflow data, which limits the ability to simulate important hydrological processes with the required level of certainty. Constraining hydrological process simulations is required to identify robust model parameters, reducing model uncertainty and providing a baseline model for climate‐related risk assessments. In this study, stable isotope measurements of rainwater, groundwater and stream water (δ2H and δ18O), together with an end member mixing analysis (EMMA) (as a post‐processing step) were integrated with the Jena adaptative modelling system (JAMS)/J2000 rainfall‐runoff model, named J2000iso. The J2000iso models of δ2H and δ18O were able to achieve a streamflow Nash–Sutcliffe efficiency (NSE) of 0.75 and 0.72 and an isotope mixing Kling–Gupta efficiency (KGE) of 0.51 and 0.60, respectively. Compared with the base version, the J2000iso had a much smaller variability with 56% less ensemble variance in the NSE, 13% more simulated interflow which resulted in a better soil‐moisture simulation at an observation point, and lower simulated flow component uncertainty. The J2000iso δ2H model was more robust than the base version during a subsequent validation in terms of KGE and Bias with 0.60 and 0.002 compared with 0.51 and −0.14 for the base version. The EMMA provided a means to improve the hydrograph separation ability of the JAMS/J2000. As many catchments around the world are still ungauged and are affected by anthropogenic activities, the development and enhancement of isotope‐enabled modelling provides a means to improve the simulation of key hydrological processes.

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“…In order to understand the relative sensitivities of the parameters θ and ones influenced by climatic disturbances, θ dry values were compared with θ wet from the NSGA-II calibration. To reduce the overall number of parameters and to include parameters with the most notable solution direction differences, parameters identified as the most sensitive in a previous study were selected for the MCA and DYNIA (Watson et al, 2021b). These parameters likewise were presumed to have the largest impact (most sensitive) on the simulated streamflow time of concentration.…”

Section: Sensitivity Analysismentioning

confidence: 99%

How Climate Extremes Influence Conceptual Rainfall-Runoff Model Performance and Uncertainty

et al. 2022

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Rainfall-runoff models are frequently used for assessing climate risks by predicting changes in streamflow and other hydrological processes due to anticipated anthropogenic climate change, climate variability, and land management. Historical observations are commonly used to calibrate empirically the performance of conceptual hydrological mechanisms. As a result, calibration procedures are limited when extrapolated to novel climate conditions under future scenarios. In this paper, rainfall-runoff model performance and the simulated catchment hydrological processes were explored using the JAMS/J2000 model for the Berg River catchment in South Africa to evaluate the model in the tails of the current distribution of climatic conditions. An evolutionary multi-objective search algorithm was used to develop sets of parameters which best simulate “wet” and “dry” periods, providing the upper and lower bounds for a temporal uncertainty analysis approach to identify variables which are affected by these climate extremes. Variables most affected included soil-water storage and timing of interflow and groundwater flow, emerging as the overall dampening of the simulated hydrograph. Previous modeling showed that the JAMS/J2000 model provided a “good” simulation for periods where the yearly long-term mean precipitation shortfall was <28%. Above this threshold, and where autumn precipitation was reduced by 50%, this paper shows that the use of a set of “dry” parameters is recommended to improve model performance. These “dry” parameters better account for the change in streamflow timing of concentration and reduced peak flows, which occur in drier winter years, improving the Nash-Sutcliffe Efficiency (NSE) from 0.26 to 0.60 for the validation period 2015–2018, although the availability of climate data was still a potential factor. As the model performance was “good” (NSE > 0.7) during “wet” periods using parameters from a long-term calibration, “wet” parameters were not recommended for the Berg River catchment, but could play a large role in tropical climates. The results of this study are likely transferrable to other conceptual rainfall/runoff models, but may differ for various climates. As greater climate variability drives hydrological changes around the world, future empirically-based hydrological projections need to evaluate assumptions regarding storage and the simulated hydrological processes, to enhanced climate risk management.

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Determining Hydrological Variability Using a Multi-Catchment Model Approach for the Western Cape, South Africa

Cited by 10 publications

References 62 publications

Between the Cape Fold Mountains and the deep blue sea: Comparative phylogeography of selected codistributed ectotherms reveals asynchronous cladogenesis

Between the Cape Fold Mountains and the deep blue sea: Comparative phylogeography of selected codistributed ectotherms reveals asynchronous cladogenesis

Towards the development of an isotope‐enabled rainfall‐runoff model: Improving the ability to capture hydrological and anthropogenic change

How Climate Extremes Influence Conceptual Rainfall-Runoff Model Performance and Uncertainty

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