2021
DOI: 10.1007/s40641-021-00171-5
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Advances in Land Surface Modelling

Abstract: Land surface models have an increasing scope. Initially designed to capture the feedbacks between the land and the atmosphere as part of weather and climate prediction, they are now used as a critical tool in the urgent need to inform policy about land-use and water-use management in a world that is changing physically and economically. This paper outlines the way that models have evolved through this change of purpose and what might the future hold. It highlights the importance of distinguishing between advan… Show more

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Cited by 90 publications
(59 citation statements)
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References 150 publications
(162 reference statements)
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“…Thereof, the by far largest source was livestock, particularly cattle in intensive agricultural systems of wealthier and emerging economies [125], with estimated emissions from enteric fermentation and manure management (the latter causing CH 4 fluxes mainly under anaerobic conditions) of 111 (106)(107)(108)(109)(110)(111)(112)(113)(114)(115)(116) Tg CH 4 year −1 [12], which is in agreement with the recent IPCC Tier 2 estimate of 99 ± 12 Tg CH 4 year −1 for 2012 [128]. Rice cultivation contributes 30 (25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38) Tg CH 4 year −1 globally, mainly due to periodic flooding and aeration of paddy rice fields and fertilization [12]. Asia contributes 30-50% to global CH 4 emissions from rice cultivation [129], but over recent decades most inventories show a decreasing trend due to reduced areal extent, changed management, and northward shift of rice cultivation [12].…”
Section: Biogeochemical Effectssupporting
confidence: 81%
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“…Thereof, the by far largest source was livestock, particularly cattle in intensive agricultural systems of wealthier and emerging economies [125], with estimated emissions from enteric fermentation and manure management (the latter causing CH 4 fluxes mainly under anaerobic conditions) of 111 (106)(107)(108)(109)(110)(111)(112)(113)(114)(115)(116) Tg CH 4 year −1 [12], which is in agreement with the recent IPCC Tier 2 estimate of 99 ± 12 Tg CH 4 year −1 for 2012 [128]. Rice cultivation contributes 30 (25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38) Tg CH 4 year −1 globally, mainly due to periodic flooding and aeration of paddy rice fields and fertilization [12]. Asia contributes 30-50% to global CH 4 emissions from rice cultivation [129], but over recent decades most inventories show a decreasing trend due to reduced areal extent, changed management, and northward shift of rice cultivation [12].…”
Section: Biogeochemical Effectssupporting
confidence: 81%
“…Basic LULCC activities were already implemented in early-generation DGVMs and have been extended steadily [2]. The improvement of LULCC representation went in parallel with relevant improvements in general land surface process representation [27]. Recent progress includes processes such as grazing, irrigation, tillage, or plant species selection (see Fig.…”
Section: Overview Of Methodsmentioning
confidence: 99%
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“…In particular, the sub-grid processes already described can 70 result in these wetter areas also being warmer, meaning that the modelled methane flux may be too low. The resolution of these sub-grid processes and the resulting heterogeneity is similarly a key challenge for other global models used for future climate projections, and needs to be addressed in order to avoid underestimating the permafrost carbon feedback (Bridgham et al, 2013;Blyth et al, 2021;Aas et al, 2019). This study therefore aims to investigate the hypothesis that explicitly modelling microtopography is essential to accurately modelling the ground moisture, temperature and hence methane emissions of a 75 permafrost landscape.…”
Section: Introduction 45mentioning
confidence: 99%
“…Water 2021, 13, 1709 2 of 16 For analysis of climate-induced streamflow extremes and water balance changes, it is necessary to simulate the spatial and temporal variability in the surface and subsurface runoff using the distributed hydrological modelling that can reflect topographic features as well as respond to meteorological forcings from the coupled or uncoupled climate application system. As for the context of the perspectives and advances in the Land Surface Models (LSMs) [10,11], the LSMs can be a useful tool to simulate the partitioning of precipitation into evapotranspiration and runoff by integrating meteorological factors and the physical geology of the land [12][13][14][15]. As the LSMs coupled to global or regional climate models simulate the water and energy exchanges between the land surface and the atmosphere, robust LSMs are required to provide a comprehensive assessment of hydrological responses to climate change at both regional and global scales [16,17].…”
Section: Introductionmentioning
confidence: 99%