The improvement of soil thermodynamics and its effects on land  surface meteorology in the IPSL climate model

Wang, F.; Chéruy, F.; Dufresne, Jean‐Louis

doi:10.5194/gmd-9-363-2016

Cited by 37 publications

(46 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Demaria, Nijssen, and Wagener () reported similar findings with the application of variable infiltration capacity model in the United States. There exist general recommendations to use deeper soil profiles with finer vertical discretization for enhanced simulation of water and energy balance in LSMs, particularly in the cold regions by climatologists (e.g., de Rosnay, Polcher, Bruen, & Laval, ; Paquin & Sushama, ; Verseghy, ; Wang et al, ). However, these more complex schemes still are relatively uncommon for coupled hydrological and ecological applications of LSSs such as MESH or CLASS‐CTEM.…”

Section: Further Discussion: Sensitivity Analysis As a Diagnostic Toolmentioning

confidence: 99%

Multicriteria sensitivity analysis as a diagnostic tool for understanding model behaviour and characterizing model uncertainty

Haghnegahdar

Razavi

Yassin

et al. 2017

Hydrological Processes

View full text Add to dashboard Cite

Complex hydrological models are being increasingly used nowadays for many purposes such as studying the impact of climate and land‐use change on water resources. However, building a high‐fidelity model, particularly at large scales, remains a challenging task, due to complexities in model functioning and behaviour and uncertainties in model structure, parameterization, and data. Global sensitivity analysis (GSA), which characterizes how the variation in the model response is attributed to variations in its input factors (e.g., parameters and forcing data), provides an opportunity to enhance the development and application of these complex models. In this paper, we advocate using GSA as an integral part of the modelling process by discussing its capabilities as a tool for diagnosing model structure and detecting potential defects, identifying influential factors, characterizing uncertainty, and selecting calibration parameters. Accordingly, we conduct a comprehensive GSA of a complex land surface–hydrology model, Modélisation Environmentale–Surface et Hydrologie (MESH), which combines the Canadian land surface scheme with a hydrological routing component, WATROUTE. Various GSA experiments are carried out using a new technique, called Variogram Analysis of Response Surfaces, for alternative hydroclimatic conditions in Canada using multiple criteria, various model configurations, and a full set of model parameters. Results from this study reveal that, in addition to different hydroclimatic conditions and SA criteria, model configurations can also have a major impact on the assessment of sensitivity. GSA can identify aspects of the model internal functioning that are counter‐intuitive and thus help the modeller to diagnose possible model deficiencies and make recommendations for improving development and application of the model. As a specific outcome of this work, a list of the most influential parameters for the MESH model is developed. This list, along with some specific recommendations, is expected to assist the wide community of MESH and Canadian land surface scheme users, to enhance their modelling applications.

show abstract

Section: Further Discussion: Sensitivity Analysis As a Diagnostic Toolmentioning

confidence: 99%

Multicriteria sensitivity analysis as a diagnostic tool for understanding model behaviour and characterizing model uncertainty

Haghnegahdar

Razavi

Yassin

et al. 2017

Hydrological Processes

View full text Add to dashboard Cite

show abstract

“…ORCHIDEE‐MICT is a land surface model that couples carbon, water, and energy dynamics and has a specific representation of high‐latitude processes (Guimberteau et al, ). For example, ORCHIDEE‐MICT incorporates permafrost physics and seasonal freeze‐thaw cycles, captures the insulation impacts of snow on soil thermal dynamics, simulates high‐latitude climatic constraints on vegetation growth, and represents the accumulation of large soil carbon stocks by limited decomposition under cold conditions and through slow vertical mixing of carbon via processes such as cryoturbation (Gouttevin et al, ; Guimberteau et al, ; T. Wang et al, ; F. Wang et al, ).…”

Section: Methodsmentioning

confidence: 99%

Matrix‐Based Sensitivity Assessment of Soil Organic Carbon Storage: A Case Study from the ORCHIDEE‐MICT Model

Huang

Zhu

Ciais

et al. 2018

J Adv Model Earth Syst

View full text Add to dashboard Cite

Modeling of global soil organic carbon (SOC) is accompanied by large uncertainties. The heavy computational requirement limits our flexibility in disentangling uncertainty sources especially in high latitudes. We build a structured sensitivity analyzing framework through reorganizing the Organizing Carbon and Hydrology in Dynamic Ecosystems (ORCHIDEE)‐aMeliorated Interactions between Carbon and Temperature (MICT) model with vertically discretized SOC into one matrix equation, which brings flexibility in comprehensive sensitivity assessment. Through Sobol's method enabled by the matrix, we systematically rank 34 relevant parameters according to variance explained by each parameter and find a strong control of carbon input and turnover time on long‐term SOC storages. From further analyses for each soil layer and regional assessment, we find that the active layer depth plays a critical role in the vertical distribution of SOC and SOC equilibrium stocks in northern high latitudes (>50°N). However, the impact of active layer depth on SOC is highly interactive and nonlinear, varying across soil layers and grid cells. The stronger impact of active layer depth on SOC comes from regions with shallow active layer depth (e.g., the northernmost part of America, Asia, and some Greenland regions). The model is sensitive to the parameter that controls vertical mixing (cryoturbation rate) but only when the vertical carbon input from vegetation is limited since the effect of vertical mixing is relatively small. And the current model structure may still lack mechanisms that effectively bury nonrecalcitrant SOC. We envision a future with more comprehensive model intercomparisons and assessments with an ensemble of land carbon models adopting the matrix‐based sensitivity framework.

show abstract

“…More recently, Wang et al . [] implemented new soil thermodynamics with a common vertical discretization for soil moisture and thermodynamics, allowing us to prescribe varying hydrothermal soil properties with depth. Peat layers for example, with high soil water holding and heat capacities, but low heat conductivity, could be mimicked, even if the current parametrization of mineral soils only accounts for quartz, water, and other mineral materials.…”

Section: Introductionmentioning

confidence: 99%

Testing the capability of ORCHIDEE land surface model to simulate Arctic ecosystems: Sensitivity analysis and site‐level model calibration

Dantec-Nédélec

Ottlé

Wang

et al. 2017

J Adv Model Earth Syst

View full text Add to dashboard Cite

The ORCHIDEE land surface model has recently been updated to improve the representation of high‐latitude environments. The model now includes improved soil thermodynamics and the representation of permafrost physical processes (soil thawing and freezing), as well as a new snow model to improve the representation of the seasonal evolution of the snow pack and the resulting insulation effects. The model was evaluated against data from the experimental sites of the WSibIso‐Megagrant project (http://www.wsibiso.ru). ORCHIDEE was applied in stand‐alone mode, on two experimental sites located in the Yamal Peninsula in the northwestern part of Siberia. These sites are representative of circumpolar‐Arctic tundra environments and differ by their respective fractions of shrub/tree cover and soil type. After performing a global sensitivity analysis to identify those parameters that have most influence on the simulation of energy and water transfers, the model was calibrated at local scale and evaluated against in situ measurements (vertical profiles of soil temperature and moisture, as well as active layer thickness) acquired during summer 2012. The results show how sensitivity analysis can identify the dominant processes and thereby reduce the parameter space for the calibration process. We also discuss the model performance at simulating the soil temperature and water content (i.e., energy and water transfers in the soil‐vegetation‐atmosphere continuum) and the contribution of the vertical discretization of the hydrothermal properties. This work clearly shows, at least at the two sites used for validation, that the new ORCHIDEE vertical discretization can represent the water and heat transfers through complex cryogenic Arctic soils—soils which present multiple horizons sometimes with peat inclusions. The improved model allows us to prescribe the vertical heterogeneity of the soil hydrothermal properties.

show abstract

The improvement of soil thermodynamics and its effects on land surface meteorology in the IPSL climate model

Cited by 37 publications

References 45 publications

Multicriteria sensitivity analysis as a diagnostic tool for understanding model behaviour and characterizing model uncertainty

Multicriteria sensitivity analysis as a diagnostic tool for understanding model behaviour and characterizing model uncertainty

Matrix‐Based Sensitivity Assessment of Soil Organic Carbon Storage: A Case Study from the ORCHIDEE‐MICT Model

Testing the capability of ORCHIDEE land surface model to simulate Arctic ecosystems: Sensitivity analysis and site‐level model calibration

Contact Info

Product

Resources

About