High-resolution global topographic index values for use in large-scale hydrological modelling

Marthews, Toby R.; Dadson, Simon; Lehner, Bernhard; Abele, Steffen; Gedney, Nicola

doi:10.5194/hess-19-91-2015

Cited by 101 publications

(88 citation statements)

References 56 publications

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“…The comparison between HydroSHEDS and GMTED also indicated that, for capturing inundated areas under the same spatial resolution, the parameter maps derived from DEM without hydrological corrections have less accuracy compared to corrected ones (Lehner and Grill, 2013). Without hydrological corrections, valleys would appear as closed depressions in the DEM, leading to an underestimation of inundated areas (Marthews et al, 2015). It could be foreseen that if DEMs in process-based models are being applied at higher resolution, this drawback could be amplified.…”

Section: Cti Parameterizationsmentioning

confidence: 99%

“…As a result, it might underestimate the wetland areas within each grid cell and slightly underestimate the temporal pattern of saturated areas because of improper estimates of parameter C s (Güntner et al, 2004). One limitation of HydroSHEDS is that its projection is not equal-area like HYDRO1k (Marthews et al, 2015) and will cause a potential bias in slope calculation along east-west directions at high latitudes. However, since there is no common method to calculate slope or flow direction, we believe that our calculations provide a reasonable approximation for global applications.…”

Section: Cti Parameterizationsmentioning

confidence: 99%

“…To avoid mismatch of CTI value inherent in computing CTI with different CTI algorithms, we generated three global CTI maps based on the three DEM products instead of relying on existing CTI products (e.g., HYDRO1k CTI, HydroSHEDS CTI product from the Centre for Ecology and Hydrology) (Marthews et al, 2015). Since studies show that multiple flow direction algorithms for calculating CTI give better accuracy compared to single-flow algorithms in flat areas (Kopecký andČížková, 2010;Pan et al, 2004), thus we selected an algorithm from R library "topmodel" (Buytaert, 2011), which applies the multiple flow routing algorithm of Quinn et al (1995) to calculate the global CTI maps.…”

Section: Topographic Informationmentioning

confidence: 99%

“…While prognostic wetland dynamics schemes are promising to resolve these observational issues, the configuration parameters for TOPMODEL are a potential source of uncertainty in estimating wetland dynamics (Marthews et al, 2015). Among all parameters in TOPMODEL, the compound topographic index (CTI) is of critical importance for determining inundated areas in terrain-related hydrological applications (Ward and Robinson, 2000;Wilson and Gallant, 2000).…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Modeling spatiotemporal dynamics of global wetlands: comprehensive evaluation of a new sub-grid TOPMODEL parameterization and uncertainties

et al. 2016

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Abstract.Simulations of the spatiotemporal dynamics of wetlands are key to understanding the role of wetland biogeochemistry under past and future climate. Hydrologic inundation models, such as the TOPography-based hydrological model (TOPMODEL), are based on a fundamental parameter known as the compound topographic index (CTI) and offer a computationally cost-efficient approach to simulate wetland dynamics at global scales. However, there remains a large discrepancy in the implementations of TOPMODEL in landsurface models (LSMs) and thus their performance against observations. This study describes new improvements to TOPMODEL implementation and estimates of global wetland dynamics using the LPJ-wsl (Lund-Potsdam-Jena Wald Schnee und Landschaft version) Dynamic Global Vegetation Model (DGVM) and quantifies uncertainties by comparing three digital elevation model (DEM) products (HYDRO1k, GMTED, and HydroSHEDS) at different spatial resolution and accuracy on simulated inundation dynamics. In addition, we found that calibrating TOPMODEL with a benchmark wetland data set can help to successfully delineate the seasonal and interannual variation of wetlands, as well as improve the spatial distribution of wetlands to be consistent with inventories. The HydroSHEDS DEM, using a riverbasin scheme for aggregating the CTI, shows the best accuracy for capturing the spatiotemporal dynamics of wetlands among the three DEM products. The estimate of global wetland potential/maximum is ∼ 10.3 Mkm 2 (10 6 km 2 ), with a mean annual maximum of ∼ 5.17 Mkm 2 for 1980-2010. When integrated with wetland methane emission submodule, the uncertainty of global annual CH 4 emissions from topography inputs is estimated to be 29.0 Tg yr −1 . This study demonstrates the feasibility of TOPMODEL to capture spatial heterogeneity of inundation at a large scale and highlights the significance of correcting maximum wetland extent to improve modeling of interannual variations in wetland area. It additionally highlights the importance of an adequate investigation of topographic indices for simulating global wetlands and shows the opportunity to converge wetland estimates across LSMs by identifying the uncertainty associated with existing wetland products.

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Section: Cti Parameterizationsmentioning

confidence: 99%

Section: Cti Parameterizationsmentioning

confidence: 99%

Section: Topographic Informationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling spatiotemporal dynamics of global wetlands: comprehensive evaluation of a new sub-grid TOPMODEL parameterization and uncertainties

et al. 2016

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“…The topographic index λ has been calculated for Great Britain at 50 m 2 resolution from the CEH-IHDTM database (Morris and Flavin, 1990;1994), following the methodology in Marthews et al (2015), and then its mean and standard deviation at the 1 km 2 model grid are used as input data for the TOPMODEL approach.…”

Section: Ancillary and Driving Data 10mentioning

confidence: 99%

Improving river flow generation over Great Britain in a land surface model required for coupled land-atmosphere interactions

Torre

Blyth

Weedon

2018

Preprint

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Abstract. Land surface models (LSMs) represent terrestrial hydrology in weather and climate modelling operational systems and research studies. Using river flow observations from gauge stations, we study the capability of the Joint UK Land Environment Simulator (JULES) LSM to simulate river flow over 13 catchments in Great Britain, each representing different climatic and topographic characteristics at the 1 km 2 spatial resolution. A series of tests, carried out to identify where the model results are 10 sensitive to the scheme and parameters chosen for runoff production, suggests that different catchments require different parameters and even different runoff schemes to produce the best results. From these results, we introduce a new topographical parametrization that produces the best daily river flow results (in terms of Nash-Sutcliffe efficiency and mean bias) for all 13 catchments. The new parametrization introduces a dependency on terrain slope, constraining surface runoff production to wet soil conditions over flatter regions (like the Thames catchment; Nash-Sutcliffe efficiency above 0.8), whereas over steeper regions the model produces surface 15 runoff for every rainfall event regardless of the soil wetness state. This new parametrization improves the model capability in regional (Great Britain wide) assessments. The new choice of parameters is reinforced by examining the amplitude and phase of the modelled versus observed river flows, via cross-spectral analysis for time scales longer than daily.

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Contribution of regional sources to atmospheric methane over the Amazon Basin in 2010 and 2011

Wilson

Gloor

Gatti

et al. 2016

Global Biogeochemical Cycles

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We present an assessment of methane (CH 4 ) atmospheric concentrations over the Amazon Basin for 2010 and 2011 using a 3-D atmospheric chemical transport model, two wetland emission models, and new observations made during biweekly flights made over four locations within the basin. We attempt to constrain basin-wide CH 4 emissions using the observations, and since 2010 was an unusually dry year, we assess the effect of this drought on Amazonian methane emissions. We find that South American emissions contribute up to 150 ppb to concentrations at the sites, mainly originating from within the basin. Our atmospheric model simulations agree reasonably well with measurements at three of the locations (0.28 ≤ r 2 ≤ 0.63, mean bias ≤ 9.5 ppb). Attempts to improve the simulated background CH 4 concentration through analysis of simulated and observed sulphur hexafluoride concentrations do not improve the model performance, however. Through minimisation of seasonal biases between the simulated and observed atmospheric concentrations, we scale our prior emission inventories to derive total basin-wide methane emissions of 36.5-41.1 Tg(CH 4 )/yr in 2010 and 31.6-38.8 Tg(CH 4 )/yr in 2011. These totals suggest that the Amazon contributes significantly (up to 7%) to global CH 4 emissions. Our analysis indicates that factors other than precipitation, such as temperature variations or tree mortality, may have affected microbial emission rates. However, given the uncertainty of our emission estimates, we cannot say definitively whether the noncombustion emissions from the region were different in 2010 and 2011, despite contrasting meteorological conditions between the two years.

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High-resolution global topographic index values for use in large-scale hydrological modelling

Cited by 101 publications

References 56 publications

Modeling spatiotemporal dynamics of global wetlands: comprehensive evaluation of a new sub-grid TOPMODEL parameterization and uncertainties

Modeling spatiotemporal dynamics of global wetlands: comprehensive evaluation of a new sub-grid TOPMODEL parameterization and uncertainties

Improving river flow generation over Great Britain in a land surface model required for coupled land-atmosphere interactions

Contribution of regional sources to atmospheric methane over the Amazon Basin in 2010 and 2011

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