Surface‐subsurface flow modeling with path‐based runoff routing, boundary condition‐based coupling, and assimilation of multisource observation data

Camporese, Matteo; Paniconi, Claudio; Putti, Mario; Orlandini, Stefano

doi:10.1029/2008wr007536

Cited by 317 publications

(362 citation statements)

References 84 publications

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“…We use the CATHY (CATchment HYdrology) model (Camporese et al, 2010) to simulate the partitioning of rainfall between runoff and infiltration, the subsurface redistribution of soil moisture and groundwater, and the discharge through the LEO seepage face. The subsurface flow module in CATHY solves the 3-D Richards equation describing flow in variably saturated porous media (Paniconi and Putti, 1994), while the surface flow module solves the diffusion wave equation describing surface flow propagation over hillslopes and in stream channels identified using terrain topography and the hydraulic geometry concept (Orlandini and Rosso, 1998).…”

Section: The Hydrological Modelmentioning

confidence: 99%

Incipient subsurface heterogeneity and its effect on overland flow generation – insight from a modeling study of the first experiment at the Biosphere 2 Landscape Evolution Observatory

Niu

Pasetto

Scudeler

et al. 2014

Hydrol. Earth Syst. Sci.

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Abstract. Evolution of landscape heterogeneity is controlled by coupled Earth system dynamics, and the resulting process complexity is a major hurdle to cross towards a unified theory of catchment hydrology. The Biosphere 2 Landscape Evolution Observatory (LEO), a 334.5 m 2 artificial hillslope built with homogeneous soil, may have evolved into heterogeneous soil during the first experiment driven by an intense rainfall event. The experiment produced predominantly seepage face water outflow, but also generated overland flow, causing superficial erosion and the formation of a small channel. In this paper, we explore the hypothesis of incipient heterogeneity development in LEO and its effect on overland flow generation by comparing the modeling results from a three-dimensional physically based hydrological model with measurements of total mass change and seepage face flow. Our null hypothesis is that the soil is hydraulically homogeneous, while the alternative hypothesis is that LEO developed downstream heterogeneity from transport of fine sediments driven by saturated subsurface flow. The heterogeneous case is modeled by assigning saturated hydraulic conductivity at the LEO seepage face (K sat,sf ) different from that of the rest (K sat ). A range of values for K sat , K sat,sf , soil porosity, and pore size distribution is used to account for uncertainties in estimating these parameters, resulting in more than 20 000 simulations. It is found that the best runs under the heterogeneous soil hypothesis produce smaller errors than those under the null hypothesis, and that the heterogeneous runs yield a higher probability of best model performance than the homogeneous runs. These results support the alternative hypothesis of localized incipient heterogeneity of the LEO soil, which facilitated generation of overland flow. This modeling study of the first LEO experiment suggests an important role of coupled water and sediment transport processes in the evolution of subsurface heterogeneity and on overland flow generation, highlighting the need of a coupled modeling system that integrates across disciplinary processes.

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Section: The Hydrological Modelmentioning

confidence: 99%

Incipient subsurface heterogeneity and its effect on overland flow generation – insight from a modeling study of the first experiment at the Biosphere 2 Landscape Evolution Observatory

Niu

Pasetto

Scudeler

et al. 2014

Hydrol. Earth Syst. Sci.

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“…With this method, the water table simulated by the saturated zone is consistent with the soil moisture profile. This class of methods can dynamically describe return flow, regional groundwater circulation, groundwater discharge, and saturation excess runoff [see also Camporese et al, 2009;Camporese et al, 2010].…”

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confidence: 99%

Improving the representation of hydrologic processes in Earth System Models

Clark

Fan

Lawrence

et al. 2015

Water Resources Research

417

404

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Many of the scientific and societal challenges in understanding and preparing for global environmental change rest upon our ability to understand and predict the water cycle change at large river basin, continent, and global scales. However, current large-scale land models (as a component of Earth System Models, or ESMs) do not yet reflect the best hydrologic process understanding or utilize the large amount of hydrologic observations for model testing. This paper discusses the opportunities and key challenges to improve hydrologic process representations and benchmarking in ESM land models, suggesting that (1) land model development can benefit from recent advances in hydrology, both through incorporating key processes (e.g., groundwater-surface water interactions) and new approaches to describe multiscale spatial variability and hydrologic connectivity; (2) accelerating model advances requires comprehensive hydrologic benchmarking in order to systematically evaluate competing alternatives, understand model weaknesses, and prioritize model development needs, and (3) stronger collaboration is needed between the hydrology and ESM modeling communities, both through greater engagement of hydrologists in ESM land model development, and through rigorous evaluation of ESM hydrology performance in research watersheds or Critical Zone Observatories. Such coordinated efforts in advancing hydrology in ESMs have the potential to substantially impact energy, carbon, and nutrient cycle prediction capabilities through the fundamental role hydrologic processes play in regulating these cycles.

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“…The red dots indicate the two endpoints along the resolutioncomplexity continuum. Models: 1: unit hydrograph (Sherman, 1932); 2: HBV (Bergström, 1992); 3: SUPERFLEX ; 4: FLEX-Topo 5: mhM (Samaniego et al, 2010); 6: mhM-topo (Nijzink et al, 2016a); 7: SWAT (Arnold et al, 1998); 8: NWS-Sacramento (Burnash, 1995); 9: GR4J (Perrin et al, 2003); 10: HYPE (Lindström et al, 2010); 11: VIC (Liang et al, 1994); 12: TOPMODEL (Beven and Kirkby, 1979); 13: CRHM; 14: TAC D (Uhlenbrook et al, 2004); 15: WASIM-ETH (Schulla and Kasper, 1998); 16: DHSVM (Wigmosta et al, 1994); 17: MIKE-SHE (Refsgaard and Storm, 1996); 18: PARFLOW ; 19: CATFLOW (Zehe et al, 2001); 20: HYDRUS-3D (Šimůnek et al, 2008); 21: CATHY (Camporese et al, 2010); 22: HydroGeoSphere (Jones et al, 2006); 23: PIHM (Qu and Duffy, 2007). and unambiguous terminology may be one of the reasons for many misunderstandings between the different model communities. We therefore think that a somewhat more rigorous model taxonomy needs to be the first step to clarify these misunderstandings and to pave the way for increased convergence of the individual modelling strategies.…”

Section: Model Taxonomymentioning

confidence: 99%

“…Bottom-up approaches are typically accomplished using distributed and physically and continuum based models (e.g. Kollet and Maxwell, 2008;Kumar et al, 2009;Camporese et al, 2010;Kollet et al, 2010;Maxwell et al, 2015;Piras et al, 2014), but strictly speaking, any kind of prediction or virtual experiment is necessarily a bottom-up approach.…”

Section: Bottom-up Modelsmentioning

confidence: 99%

HESS Opinions: The complementary merits of competing modelling philosophies in hydrology

Hrachowitz

Clark

2017

Hydrol. Earth Syst. Sci.

165

130

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Abstract. In hydrology, two somewhat competing philosophies form the basis of most process-based models. At one endpoint of this continuum are detailed, high-resolution descriptions of small-scale processes that are numerically integrated to larger scales (e.g. catchments). At the other endpoint of the continuum are spatially lumped representations of the system that express the hydrological response via, in the extreme case, a single linear transfer function. Many other models, developed starting from these two contrasting endpoints, plot along this continuum with different degrees of spatial resolutions and process complexities. A better understanding of the respective basis as well as the respective shortcomings of different modelling philosophies has the potential to improve our models. In this paper we analyse several frequently communicated beliefs and assumptions to identify, discuss and emphasize the functional similarity of the seemingly competing modelling philosophies. We argue that deficiencies in model applications largely do not depend on the modelling philosophy, although some models may be more suitable for specific applications than others and vice versa, but rather on the way a model is implemented. Based on the premises that any model can be implemented at any desired degree of detail and that any type of model remains to some degree conceptual, we argue that a convergence of modelling strategies may hold some value for advancing the development of hydrological models.

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Surface‐subsurface flow modeling with path‐based runoff routing, boundary condition‐based coupling, and assimilation of multisource observation data

Cited by 317 publications

References 84 publications

Incipient subsurface heterogeneity and its effect on overland flow generation – insight from a modeling study of the first experiment at the Biosphere 2 Landscape Evolution Observatory

Incipient subsurface heterogeneity and its effect on overland flow generation – insight from a modeling study of the first experiment at the Biosphere 2 Landscape Evolution Observatory

Improving the representation of hydrologic processes in Earth System Models

HESS Opinions: The complementary merits of competing modelling philosophies in hydrology

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