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1. The time validity of Philip's two‐term infiltration equation: An elusive theoretical quantity?

Author

Vrugt, Jasper A, Hopmans, Jan W, Gao, Yifu, Rahmati, Mehdi, Vanderborght, Jan, and Vereecken, Harry

Subjects
Hydrology, Environmental Sciences, Earth Sciences, Soil Sciences, Physical Geography and Environmental Geoscience, Crop and Pasture Production, Environmental Engineering, Soil sciences
Abstract

The two-term infiltration equation (Formula presented.) is commonly used to determine the sorptivity, (Formula presented.) (Formula presented.), and product, (Formula presented.) (Formula presented.), of the dimensionless multiple (Formula presented.) and saturated soil hydraulic conductivity (Formula presented.) (Formula presented.) from cumulative vertical infiltration measurements (Formula presented.) (L) at times (Formula presented.) (T). This reduced form of the quasi-analytical power series solution of Richardson's equation of Philip enjoys a solid physical underpinning but at the expense of a limited time validity. Using simulated infiltration data, Jaiswal et al. have shown this time validity to equal about 2.5 cm of cumulative infiltration. The goals of this work are twofold. First, we investigate the extent to which cumulative infiltration measurements larger than 2.5 cm bias the estimates of (Formula presented.) and (Formula presented.). Second, we investigate the impact of epistemic errors on the inferred time validities and parameters. Partial infiltration curves up to 2.5 cm of cumulative vertical infiltration improve substantially the agreement between actual and least squares estimates of (Formula presented.) and (Formula presented.). But this only holds if the data generating infiltration process follows Richardson's equation and experimental conditions satisfy assumptions of soil homogeneity and a uniform initial water content. Otherwise, autocorrelated cumulative infiltration residuals will bias the least squares estimates of (Formula presented.) and (Formula presented.). Our findings reiterate and reinvigorate earlier conclusions of Haverkamp et al. and show that epistemic errors deteriorate the physical significance of the coefficients of infiltration functions. As a result, the parameters of infiltration functions cannot simply be used in storm water and vadose zone flow models to forecast runoff and recharge at field and landscape scales unless these predictions are accompanied by realistic uncertainty bounds. We conclude that the time validity of Philip's two-term equation is an elusive theoretical quantity with arbitrary physical meaning.

Published
2024

2. Continuous increase in evaporative demand shortened the growing season of European ecosystems in the last decade

Author

Rahmati, Mehdi, Graf, Alexander, Poppe Terán, Christian, Amelung, Wulf, Dorigo, Wouter, Franssen, Harrie-Jan Hendricks, Montzka, Carsten, Or, Dani, Sprenger, Matthias, Vanderborght, Jan, Verhoest, Niko EC, and Vereecken, Harry

Subjects
Clean Water and Sanitation
Abstract

Despite previous reports on European growing seasons lengthening due to global warming, evidence shows that this trend has been reversing in the past decade due to increased transpiration needs. To asses this, we used an innovative method along with space-based observations to determine the timing of greening and dormancy and then to determine existing trends of them and causes. Early greening still occurs, albeit at slower rates than before. However, a recent (2011–2020) shift in the timing of dormancy has caused the season length to decrease back to 1980s levels. This shortening of season length is attributed primarily to higher atmospheric water demand in summer that suppresses transpiration even for soil moisture levels as of previous years. Transpiration suppression implies that vegetation is unable to meet the high transpiration needs. Our results have implications for future management of European ecosystems (e.g., net carbon balance and water and energy exchange with atmosphere) in a warmer world.

Published
2023

4. Parasite inversion for determining the coefficients and time‐validity of Philip's two‐term infiltration equation

Author

Jaiswal, Parakh, Gao, Yifu, Rahmati, Mehdi, Vanderborght, Jan, Šimůnek, Jirka, Vereecken, Harry, and Vrugt, Jasper A

Subjects
Physical Geography and Environmental Geoscience, Soil Sciences, Crop and Pasture Production, Environmental Engineering
Abstract

Many different equations have been proposed to describe quantitatively one-dimensional soil water infiltration. The unknown coefficients of these equations characterize soil hydraulic properties and may be estimated from a n record, (Formula presented.), of cumulative infiltration measurements using curve fitting techniques. The two-term infiltration equation, (Formula presented.), of Philip has been widely used to describe measured infiltration data. This function enjoys a solid mathematical–physical underpinning and admits a closed-form solution for the soil sorptivity, S [L T−1/2], and multiple, c [−], of the saturated hydraulic conductivity, Ks [L T−1]. However, Philip's two-term equation has a limited time validity, tvalid [T], and thus cumulative infiltration data, (Formula presented.), beyond (Formula presented.) will corrupt the estimates of S and Ks. This paper introduces a novel method for estimating S, c, Ks, and tvalid of Philip's two-term infiltration equation. This method, coined parasite inversion, use as vehicle Parlange's three-parameter infiltration equation. As prerequisite to our method, we present as secondary contribution an exact, robust and efficient numerical solution of Parlange's infiltration equation. This solution admits Bayesian parameter estimation with the DiffeRential Evolution Adaptive Metropolis (DREAM) algorithm and yields as byproduct the marginal distribution of Parlange's β parameter. We evaluate our method for 12 USDA soil types using synthetic infiltration data simulated with HYDRUS-1D. An excellent match is observed between the inferred values of S and Ks and their “true” values known beforehand. Furthermore, our estimates of c and tvalid correlate well with soil texture, corroborate linearity of the (Formula presented.) relationship for (Formula presented.), and fall within reported ranges. A cumulative vertical infiltration of about 2.5 cm may serve as guideline for the time-validity of Philip's two-term infiltration equation.

Published
2022

5. Limited effects of crop foliar Si fertilization on a marginal soil under a future climate scenario

Author

Rineau, Francois, Groh, Jannis, Claes, Julie, Grosjean, Kristof, Mench, Michel, Moreno-Druet, Maria, Povilaitis, Virmantas, Pütz, Thomas, Rutkowska, Beata, Schröder, Peter, Soudzilovskaia, Nadejda A., Swinnen, Xander, Szulc, Wieslaw, Thijs, Sofie, Vanderborght, Jan, Vangronsveld, Jaco, Vereecken, Harry, Verhaege, Kasper, Žydelis, Renaldas, and Loit, Evelin

Published
2024
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6. Soil hydraulic properties estimation from one‐dimensional infiltration experiments using characteristic time concept

Author

Rahmati, Mehdi, Vanderborght, Jan, Šimůnek, Jirka, Vrugt, Jasper A, Moret‐Fernández, David, Latorre, Borja, Lassabatere, Laurent, and Vereecken, Harry

Subjects
Physical Geography and Environmental Geoscience, Soil Sciences, Crop and Pasture Production, Environmental Engineering
Abstract

Many different equations ranging from simple empirical to semi-analytical solutions of the Richards equation have been proposed for quantitative description of water infiltration into variably saturated soils. The sorptivity, S, and the saturated hydraulic conductivity, Ks, in these equations are typically unknown and have to be estimated from measured data. In this paper, we use so-called characteristic time (tchar) to design a new method, referred to as the characteristic time method (CTM) that estimates S, and Ks, from one-dimensional (1D) cumulative infiltration data. We demonstrate the usefulness and power of the CTM by comparing it with a suite of existing methods using synthetic cumulative infiltration data simulated by HYDRUS-1D for 12 synthetic soils reflecting different USDA textural classes, as well as experimental data selected from the Soil Water Infiltration Global (SWIG) database. Results demonstrate that the inferred values of S and Ks are in excellent agreement with their theoretical values used in the synthetically simulated infiltration experiments with Nash–Sutcliffe criterion close to unity and RMSE values of 0.04 cm h−1/2 and 0.05 cm h−1, respectively. The CTM also showed very high accuracy when applied on synthetic data with added measurement noise, as well as robustness when applied to experimental data. Unlike previously published methods, the CTM does not require knowledge of the time validity of the applied semi-analytical solution for infiltration and, therefore, is applicable to infiltrations with durations from 5 min to several days. A script written in Python of the CTM method is provided in the supplemental material.

Published
2020

7. Infiltration from the Pedon to Global Grid Scales: An Overview and Outlook for Land Surface Modeling

Author

Vereecken, Harry, Weihermüller, Lutz, Assouline, Shmuel, Šimůnek, Jirka, Verhoef, Anne, Herbst, Michael, Archer, Nicole, Mohanty, Binayak, Montzka, Carsten, Vanderborght, Jan, Balsamo, Gianpaolo, Bechtold, Michel, Boone, Aaron, Chadburn, Sarah, Cuntz, Matthias, Decharme, Bertrand, Ducharne, Agnès, Ek, Michael, Garrigues, Sebastien, Goergen, Klaus, Ingwersen, Joachim, Kollet, Stefan, Lawrence, David M, Li, Qian, Or, Dani, Swenson, Sean, Vrese, Philipp, Walko, Robert, Wu, Yihua, and Xue, Yongkang

Subjects
Physical Geography and Environmental Geoscience, Soil Sciences, Crop and Pasture Production, Environmental Engineering
Abstract

Infiltration in soils is a key process that partitions precipitation at the land surface into surface runoff and water that enters the soil profile. We reviewed the basic principles of water infiltration in soils and we analyzed approaches commonly used in land surface models (LSMs) to quantify infiltration as well as its numerical implementation and sensitivity to model parameters. We reviewed methods to upscale infiltration from the point to the field, hillslope, and grid cell scales of LSMs. Despite the progress that has been made, upscaling of local-scale infiltration processes to the grid scale used in LSMs is still far from being treated rigorously. We still lack a consistent theoretical framework to predict effective fluxes and parameters that control infiltration in LSMs. Our analysis shows that there is a large variety of approaches used to estimate soil hydraulic properties. Novel, highly resolved soil information at higher resolutions than the grid scale of LSMs may help in better quantifying subgrid variability of key infiltration parameters. Currently, only a few LSMs consider the impact of soil structure on soil hydraulic properties. Finally, we identified several processes not yet considered in LSMs that are known to strongly influence infiltration. Especially, the impact of soil structure on infiltration requires further research. To tackle these challenges and integrate current knowledge on soil processes affecting infiltration processes into LSMs, we advocate a stronger exchange and scientific interaction between the soil and the land surface modeling communities.

Published
2019

11. Temporal covariance of spatial soil moisture variations: A mechanistic error modeling approach.

Author

Hendrickx, Marit G. A., Diels, Jan, Janssens, Pieter, Schlüter, Steffen, and Vanderborght, Jan

Subjects
SOIL moisture, SOIL moisture measurement, MEASUREMENT errors, FIELD research, SENSOR placement
Abstract

When estimating field‐scale average soil moisture from sensors measuring at fixed positions, spatial variability in soil moisture leads to "measurement errors" of the spatial mean, which may persist over time due to persistent soil moisture patterns resulting in autocorrelated measurement errors. The uncertainty of parameters that are derived from such measurements may be underestimated when they are assumed to be independent. Temporal autocorrelation models assume stationary random errors, but such error models are not necessarily applicable to soil moisture measurements. As an alternative, we propose a mechanistic error model that is based on the spatial variability of the water retention curve and assumes a uniform water potential. We tested whether spatial soil moisture variability and its temporal covariance could be predicted based on (1) mean soil moisture, (2) water retention variability, and (3) (co)variances of the van Genuchten parameters using a first‐order expansion of the retention curve. The proposed models were tested in a numerical and a field experiment. For the field experiment, in situ sensor measurements and water retention curves were obtained in a field plot. Both experiments showed that water retention variability under a uniform water potential is a good predictor for spatial soil moisture variability, and that soil moisture errors are strongly correlated in time and neglecting them would be an incorrect assumption. The temporal error covariance could be predicted as a function of the mean moisture contents at two observation times. Further research is required to assess the impact of these temporal correlations on soil moisture predictions. Core Ideas: Soil moisture is spatially variable, and spatial variations are correlated in time.Due to spatial variability, the estimated average soil moisture from a limited number of measurements is uncertain.The error of the spatial mean estimated from a limited number of sensors at fixed positions is correlated in time.A mechanistic error modeling approach is presented based on the spatial variability of the water retention curve.Such a model can predict measurement variability and error covariance in time as a function of mean soil moisture. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Combining root and soil hydraulics in macroscopic representations of root water uptake.

Author

Vanderborght, Jan, Leitner, Daniel, Schnepf, Andrea, Couvreur, Valentin, Vereecken, Harry, and Javaux, Mathieu

Subjects
ONE-dimensional flow, RADIAL flow, PLANT-water relationships, HYDRAULICS, SOIL permeability, SOILS
Abstract

Plant water uptake and plant and soil water status are important for the soil water balance and plant growth. They depend on atmospheric water demand and the accessibility of soil water to plant roots, which is in turn related to the hydraulic properties of the root system and the soil around root segments. We present a simulation model that describes water flow in the soil–plant system mechanistically considering both root and soil hydraulic properties. We developed an approach to upscale three‐dimensional (3D) flow in the soil toward root segments of a 3D root architecture to a model that considers one‐dimensional flow between horizontal soil layers and radial flow to root segments in that layer. The upscaled model couples upscaled linear flow equations in the root system with an analytical solution of the nonlinear radial flow equation between the soil and roots. The upscaled model avoids simplifying assumptions about root hydraulic properties and water potential drops near roots made in, respectively, soil‐ and root‐centered models. Xylem water potentials and soil–root interface potentials are explicitly simulated and show, respectively, large variations with depth and large deviations from bulk soil water potentials under dry soil conditions. Accounting for hydraulic gradients in the soil around root segments led to an earlier but slower reduction of transpiration during a drought period and a better plant water status with higher nighttime plant water potentials. Core Ideas: Root water uptake depends on root and soil hydraulic properties.Water uptake at root element scale was upscaled to the root system scale.The upscaled model can be implemented in one‐dimensional soil water flow models.Low conductance of dry soil prevents low nighttime plant water potentials. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Root hydraulic properties: An exploration of their variability across scales.

Author

Baca Cabrera, Juan C., Vanderborght, Jan, Couvreur, Valentin, Behrend, Dominik, Gaiser, Thomas, Nguyen, Thuy Huu, and Lobet, Guillaume

Subjects
CULTIVARS, DATABASES, WOODY plants, PLANT variation, AQUAPORINS, DYNAMIC simulation
Abstract

Root hydraulic properties are key physiological traits that determine the capacity of root systems to take up water, at a specific evaporative demand. They can strongly vary among species, cultivars or even within the same genotype, but a systematic analysis of their variation across plant functional types (PFTs) is still missing. Here, we reviewed published empirical studies on root hydraulic properties at the segment‐, individual root‐, or root system scale and determined its variability and the main factors contributing to it. This corresponded to a total of 241 published studies, comprising 213 species, including woody and herbaceous vegetation. We observed an extremely large range of variation (of orders of magnitude) in root hydraulic properties, but this was not caused by systematic differences among PFTs. Rather, the (combined) effect of factors such as root system age, driving force used for measurement, or stress treatments shaped the results. We found a significant decrease in root hydraulic properties under stress conditions (drought and aquaporin inhibition, p <.001) and a significant effect of the driving force used for measurement (hydrostatic or osmotic gradients, p <.001). Furthermore, whole root system conductance increased significantly with root system age across several crop species (p <.01), causing very large variation in the data (>2 orders of magnitude). Interestingly, this relationship showed an asymptotic shape, with a steep increase during the first days of growth and a flattening out at later stages of development. We confirmed this dynamic through simulations using a state‐of‐the‐art computational model of water flow in the root system for a variety of crop species, suggesting common patterns across studies and species. These findings provide better understanding of the main causes of root hydraulic properties variations observed across empirical studies. They also open the door to better representation of hydraulic processes across multiple plant functional types and at large scales. All data collected in our analysis has been aggregated into an open access database (https://roothydraulic-properties.shinyapps.io/database/), fostering scientific exchange. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Responses of field-grown maize to different soil types, water regimes, and contrasting vapor pressure deficit.

Author

Thuy Huu Nguyen, Gaiser, Thomas, Vanderborght, Jan, Schnepf, Andrea, Bauer, Felix, Klotzsche, Anja, Lärm, Lena, Hüging, Hubert, and Ewert, Frank

Subjects
SOIL classification, VAPOR pressure, PLANT breeding, IRRIGATED soils, CORN, CROPPING systems
Abstract

Drought is a serious constraint to crop growth and production of important staple crops such as maize. Improved understanding of the responses of crops to drought can be incorporated into cropping system models to support crop breeding, varietal selection and management decisions for minimizing negative impacts. We investigate the impacts of different soil types (stony and silty) and water regimes (irrigated and rainfed) on hydraulic linkages between soil and plant, as well as root: shoot growth characteristics. Our analysis is based on a comprehensive dataset measured along the soil-plant-atmosphere pathway at field scale in two growing seasons (2017, 2018) with contrasting climatic conditions (low and high VPD). Roots were observed mostly in the topsoil (10-20 cm) of the stony soil while more roots were found in the subsoil (60-80 cm) of the silty soil. The difference in root length was pronounced at silking and harvest between the soil types. Total root length was 2.5 - 6 times higher in the silty soil compared to the stony soil with the same water treatment. At silking time, the ratios of root length to shoot biomass in the rainfed plot of the silty soil (F2P2) were 3 times higher than those in the irrigated silty soil (F2P3) while the ratio was similar for two water treatments in the stony soil. With the same water treatment, the ratios of root length to shoot biomass of silty soil was higher than stony soil. The observed minimum leaf water potential (ψleaf) varied from around -1.5 MPa in the rainfed plot in 2017 to around -2.5 MPa in the same plot of the stony soil in 2018. In the rainfed plot, the mimimum ψleaf in the stony soil was lower than in silty soil from -2 to -1.5 MPa in 2017, respectively while these were from -2.5 to -2 MPa in 2018, respectively. Leaf water potential, water potential gradients from soil to plant roots, plant hydraulic conductance (Ksoil_plant), stomatal conductance, transpiration, and photosynthesis were considerably modulated by the soil water content and the conductivity of the rhizosphere. When the stony soil and silt soil are compared, the higher 'stress' due to the lower water availability in the stony soil resulted in less roots with a higher root tissue conductance in the soil with more stress. When comparing the rainfed with the irrigated plot in the silty soil, the higher stress in the rainfed soil resulted in more roots with a lower root tissue conductance in the treatment with more stress. This illustrates that the 'response' to stress can be completely opposite depending on conditions or treatments that lead to the differences in stress that are compared. To respond to water deficit, maize had higher water uptake rate per unit root length and higher root segment conductance in the stony soil than in the silty soil, while the crop reduced transpired water via reduced aboveground plant size. Future improvements of soil-crop models in simulating gas exchange and crop growth should further emphasize the role of soil textures on stomatal function, dynamic root growth, and plant hydraulic system together with aboveground leaf area adjustments. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Linking horizontal crosshole GPR variability with root image information for maize crops.

Author

Lärm, Lena, Bauer, Felix Maximilian, van der Kruk, Jan, Vanderborght, Jan, Morandage, Shehan, Vereecken, Harry, Schnepf, Andrea, and Klotzsche, Anja

Subjects
GROUND penetrating radar, GROWING season, PROBABILITY density function, SOIL compaction, SOIL classification
Abstract

Non‐invasive imaging of processes within the soil–plant continuum, particularly root and soil water distributions, can help optimize agricultural practices such as irrigation and fertilization. In this study, in‐situ time‐lapse horizontal crosshole ground penetrating radar (GPR) measurements and root images were collected over three maize crop growing seasons at two minirhizotron facilities (Selhausen, Germany). Root development and GPR permittivity were monitored at six depths (0.1–1.2 m) for different treatments within two soil types. We processed these data in a new way that gave us the information of the "trend‐corrected spatial permittivity deviation of vegetated field," allowing us to investigate whether the presence of roots increases the variability of GPR permittivity in the soil. This removed the main non‐root‐related influencing factors: static influences, such as soil heterogeneities and rhizotube deviations, and dynamic effects, such as seasonal moisture changes. This trend‐corrected spatial permittivity deviation showed a clear increase during the growing season, which could be linked with a similar increase in root volume fraction. Additionally, the corresponding probability density functions of the permittivity variability were derived and cross‐correlated with the root volume fraction, resulting in a coefficient of determination (R2) above 0.5 for 23 out of 46 correlation pairs. Although both facilities had different soil types and compaction levels, they had similar numbers of good correlations. A possible explanation for the observed correlation is that the presence of roots causes a redistribution of soil water, and therefore an increase in soil water variability. Core Ideas: Analying spatial and temporal belowground GPR signal variability and root images for maize crop roots.Root images and GPR data show differences for different treatments.Linking of root volume fraction and GPR permittivity variability. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Collaborative benchmarking of functional-structural root architecture models: Quantitative comparison of simulated root water uptake

Author

Schnepf, Andrea, primary, Black, Christopher K, additional, Couvreur, Valentin, additional, Delory, Benjamin M, additional, Doussan, Claude, additional, Heymans, Adrien, additional, Javaux, Mathieu, additional, Khare, Deepanshu, additional, Koch, Axelle, additional, Koch, Timo, additional, Kuppe, Christian W, additional, Landl, Magdalena, additional, Leitner, Daniel, additional, Lobet, Guillaume, additional, Meunier, Félicien, additional, Postma, Johannes A, additional, Schäfer, Ernst D, additional, Selzner, Tobias, additional, Vanderborght, Jan, additional, and Vereecken, Harry, additional

Published
2023
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26. Collaborative benchmarking of functional-structural root architecture models: Quantitative comparison of simulated root water uptake

Author

Schnepf, Andrea, Black, Christopher K, Couvreur, Valentin, Delory, Benjamin M, Doussan, Claude, Heymans, Adrien, Javaux, Mathieu, Khare, Deepanshu, Koch, Axelle, Koch, Timo, Kuppe, Christian W, Landl, Magdalena, Leitner, Daniel, Lobet, Guillaume, Meunier, Félicien, Postma, Johannes A, Schäfer, Ernst D, Selzner, Tobias, Vanderborght, Jan, Vereecken, Harry, and UCL - SST/ELI/ELIA - Agronomy

Subjects
Modeling and Simulation, Plant Science, Genetics and Molecular Biology (miscellaneous), Agronomy and Crop Science, Biochemistry
Abstract

Functional structural root architecture models have evolved as tools for the design of improved agricultural management practices and for the selection of optimal root traits. In order to test their accuracy and reliability, we present the first benchmarking of root water uptake from soil using five well established functional structural root architecture models: DuMux, CPlantBox, RSWMS, OpenSimRoot and SRI. The benchmark scenarios include basic tests for water flow in soil and roots as well as advanced tests for the coupled soil root system. The reference solutions and the solutions of the different simulators are available through Jupyter Notebooks on a GitHub repository. All of the simulators were able to pass the basic tests and continued to perform well in the benchmarks for the coupled soil-plant system. For the advanced tests, we created an overview of the different ways of coupling the soil and the root domains as well as the different methods used to account for rhizosphere resistance to water flow. Although the methods used for coupling and modelling rhizosphere resistance were quite different, all simulators were in reasonably good agreement with the reference solution. During this benchmarking effort, individual simulators were able to learn about their strengths and challenges, while some were even able to improve their code. Some now include the benchmarks as standard tests within their codes. Additional model results may be added to the GitHub repository at any point in the future and will be automatically included in the comparison.

Published
2023

27. Lagged correlation between soil water content and evapotranspiration along recent decades and across different land cover types of Europe

Author

Rahmati, Mehdi, Graf, Alexander, Bayat, Bagher, Montzka, Carsten, Poppe, Christian, Vanderborght, Jan, Hendricks-Franssen, Harrie-Jan, and Harry Vereecken, Harry Vereecken

Abstract

The link between soil water content (SWC) and evapotranspiration (ET) is of great importance in ecohydrology, agroecosystem management, and land-atmosphere interaction of earth-system analysis. There is still a need to understand the key processes linking SWC and ET in different vegetated ecosystems, especially at larger scales. Therefore, in this work, we used wavelet coherence analysis to explore the long-term relationship between SWC and ET among the predominant land use types (cropland, evergreen needleleaf forest, mixed forest, open shrubland, wooden tundra, grassland, and mixed tundra) in Europe during the last four decades (1980-2020). To this end, first a principal component analysis was performed among the SWC and ET data from GLDAS, GLEAM, and ERA5-land, and the first component was then used for further analyses when the target variable was in demand. Using the first component, then, we averaged SWC and ET data over the pixels covered by each land use type. Then, for each land-use types, we averaged the data daily for each decade to account for a representative decadal year of daily data. Then, wavelet coherence analysis was conducted between those averaged data of SWC and ET for each land-use type. The results showed a negative correlation between ET and SWC for all land use types, with ET lagging behind SWC, with an average phase shift value of 134 days for grassland (the minimum) and 168 days for mixed tundra (the maximum). Converting the phase shift values to a time lag [lag = n/2 - phase shift for the case phase shift < -n/4 where n represents the period (1/frequency) of the signals] shows (Fig. 1) that ET controls SWC with a lag of 15 days in mixed tundra (the minimum) and 48 days in grassland (the maximum). Moreover, we applied Mann-Kendall trend analysis test and found that the lag between SWC and ET decreases in mixed and wooden tundras with a slope value of -2.4 days/year, while it increases in cropland and grassland with a slope value of 1.6 days/year. Although there is a significant downward trend in evergreen needleleaf forests (with a slope value of -0.3 days/year) and an increasing trend in mixed forests and open shrublands (with a slope value of 0.4 days/year), the lower slope values in these land use types indicate that the change is slower compared to grasslands, croplands, and tundras. Figure 1- Temporal evolution of the lag between soil water content and evapotranspiration in the annual cycle in different land use types in Europe

Published
2023
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28. SUPPLEMENT : MONITORING AND MODELING THE TERRESTRIAL SYSTEM FROM PORES TO CATCHMENTS The Transregional Collaborative Research Center on Patterns in the Soil—Vegetation—Atmosphere System

Author

Simmer, Clemens, Thiele-Eich, Insa, Masbou, Matthieu, Amelung, Wulf, Bogena, Heye, Crewell, Susanne, Diekkrüger, Bernd, Ewert, Frank, Franssen, Harrie-Jan Hendricks, Huisman, Johan Alexander, Kemna, Andreas, Klitzsch, Norbert, Kollet, Stefan, Langensiepen, Matthias, Löhnert, Ulrich, Rahman, A. S. M. Mostaquimur, Rascher, Uwe, Schneider, Karl, Schween, Jan, Shao, Yaping, Shrestha, Prabhakar, Stiebler, Maik, Sulis, Mauro, Vanderborght, Jan, Vereecken, Harry, van der Kruk, Jan, Zerenner, Tanja, and Waldhoff, Guido

Published
2015

29. MONITORING AND MODELING THE TERRESTRIAL SYSTEM FROM PORES TO CATCHMENTS : The Transregional Collaborative Research Center on Patterns in the Soil–Vegetation–Atmosphere System

Author

Simmer, Clemens, Thiele-Eich, Insa, Masbou, Matthieu, Amelung, Wulf, Bogena, Heye, Crewell, Susanne, Diekkrüger, Bernd, Ewert, Frank, Franssen, Harrie-Jan Hendricks, Huisman, Johan Alexander, Kemna, Andreas, Klitzsch, Norbert, Kollet, Stefan, Langensiepen, Matthias, Löhnert, Ulrich, Rahman, A. S. M. Mostaquimur, Rascher, Uwe, Schneider, Karl, Schween, Jan, Shao, Yaping, Shrestha, Prabhakar, Stiebler, Maik, Sulis, Mauro, Vanderborght, Jan, Vereecken, Harry, van der Kruk, Jan, Waldhoff, Guido, and Zerenner, Tanja

Published
2015

30. Soil hydrology in the Earth system

Author

Vereecken, Harry, Amelung, Wulf, Bauke, Sarah L., Bogena, Heye, Brüggemann, Nicolas, Montzka, Carsten, Vanderborght, Jan, Bechtold, Michel, Blöschl, Günter, Carminati, Andrea, Javaux, Mathieu, Konings, Alexandra G., Kusche, Jürgen, Neuweiler, Insa, Or, Dani, Steele-Dunne, Susan, Verhoef, Anne, Young, Michael, Zhang, Yonggen, Agrosphere Institute, IBG-3, Forschungszentrum Jülich GmbH, 52428 Jülich, Germany, Institute of Crop Science and Resource Conservation (INRES) - Soil Science and Soil Ecology, University of Bonn, Germany, Department of Earth and Environmental Sciences, KU Leuven, Belgium, Institute of Hydraulic and Water Resources Engineering, Technische Universitat Wien, Karlsplatz 13/222, 1040, Vienna, Austria, Dep. of Environmental Systems Science, ETH, Zürich, Switzerland, Earth and Life Institute, Environmental Sciences, Université Catholique de Louvain, Louvain-la-Neuve, Belgium, Department of Earth System Science, Stanford, California, US, Institute of Geodesy and Geoinformation, University of Bonn, Nussallee 17, 53115 Bonn, Germany, Hannover University, Institut für Strömungsmechanik und Umweltphysik im Bauwesen, Hannover University, Germany, Swiss Federal Institute of Technology (ETH Zurich), Zurich, Switzerland, dani.or@env.ethz.ch and Division of Hydrologic Sciences, Desert Research Institute, Reno, NV, USA, Department of Geoscience and Remote Sensing, TU Delft, The Netherlands, Department of Geography and Environmental Science, The University of Reading, Reading, UK, Bureau of Economic Geology, Jackson School of Geosciences, University of Texas at Austin, USA, and School of Earth System Science, Tianjin University, China, ygzhang@tju.edu.cn

Abstract

Predicting the impact of land use and climate change on the Earth system hinges on credible representation of soil hydrological processes (SHP), adequate availability of parameters and hydrological states and inclusion of key soil properties. There is increasing evidence that extreme events such as droughts and high intensity precipitation, and land use changes, affect fundamental hydrological processes such as infiltration and runoff generation. In this review, we analyse the influence of soil structure on SHP, critically evaluate the parameterization of soil hydrologic properties and their importance in representing the terrestrial water cycle and highlight the key role of soil hydrology in the functioning of carbon-rich soils and in linking the water and carbon cycles. It emerges that linking soil hydrology and pedology will lead to better understanding critical zone processes, especially in tropical regions. Further, we discuss the role of local scale hydrological processes in understanding root water uptake, vegetation and groundwater dynamics and feedbacks. These processes control and modulate the impact of extreme events such as droughts, floods and heatwaves and they are essential to assess drought and flooding. Finally, new emerging technologies such as wireless and automated sensing approaches, soil moisture observation through novel synthetic aperture radars satellites, big data analysis and machine learning approaches offer unique opportunities to advance soil hydrology.

Published
2022

34. On Infiltration and Infiltration Characteristic Times

Author

Rahmati, Mehdi, Latorre, Borja, Moret‐Fernández, David, Lassabatere, Laurent, Talebian, Nima, Miller, Dane, Morbidelli, Renato, Iovino, Massimo, Bagarello, Vincenzo, Neyshabouri, Mohammad Reza, Zhao, Ying, Vanderborght, Jan, Weihermüller, Lutz, Jaramillo, Rafael Angulo, Or, Dani, Genuchten, Martinus van, Vereecken, Harry, Hydrogeology, Environmental hydrogeology, Hydrogeology, Environmental hydrogeology, Latorre Garcés, Borja, Moret-Fernández, David, Department of Soil Science and Engineering, Faculty of Agriculture, University of Maragheh, Institute of Bio- and Geosciences [Jülich] (IBG), Forschungszentrum Jülich GmbH | Centre de recherche de Juliers, Helmholtz-Gemeinschaft = Helmholtz Association-Helmholtz-Gemeinschaft = Helmholtz Association, Consejo Superior de Investigaciones Científicas [Spain] (CSIC), Departamento de Suelo y Agua, Pomology Department, Estación Experimental de Aula Dei, Équipe 5 - Impact des Aménagements et des Polluants sur les HYdrosystèmes (IAPHY), Laboratoire d'Ecologie des Hydrosystèmes Naturels et Anthropisés (LEHNA), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-École Nationale des Travaux Publics de l'État (ENTPE)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-École Nationale des Travaux Publics de l'État (ENTPE)-Centre National de la Recherche Scientifique (CNRS), Bond University [Gold Coast], Department of Civil and Environmental Engineering of the University of Perugia, Italy, Università degli Studi di Perugia = University of Perugia (UNIPG), Università degli studi di Palermo - University of Palermo, University of Tabriz [Tabriz], College of Resources and Environmental Engineering [Yantai], Ludong University, Desert Research Institute (DRI), Department of Environmental Systems Science [ETH Zürich] (D-USYS), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Department of Earth Sciences, Utrecht University, Center for Environmental Studies, CEA, São Paulo State University, Latorre Garcés, Borja [0000-0002-6720-3326], Moret-Fernández, David [0000-0002-6674-0453], Rahmati M., Latorre B., Moret-Fernandez D., Lassabatere L., Talebian N., Miller D., Morbidelli R., Iovino M., Bagarello V., Neyshabouri M.R., Zhao Y., Vanderborght J., Weihermuller L., Jaramillo R.A., Or D., Th. van Genuchten M., and Vereecken H.

Subjects
Science & Technology, EROSION, sorptivity, HYDRAULIC CONDUCTIVITY, INFILTROMETER, Infiltration, Environmental Sciences & Ecology, PARAMETERS, SOIL, MODEL, Physical Sciences, Limnology, [SDE]Environmental Sciences, ddc:550, Water Resources, EQUATION, Settore AGR/08 - Idraulica Agraria E Sistemazioni Idraulico-Forestali, WATER, steady state, time domain validity, Marine & Freshwater Biology, Life Sciences & Biomedicine, hydraulic conductivity, Environmental Sciences, Water Science and Technology
Abstract

In his seminal paper on the solution of the infiltration equation, Philip (1969), https://doi.org/10.1016/b978-1-4831-9936-8.50010-6 proposed a gravity time, tgrav, to estimate practical convergence time and the time domain validity of his infinite time series expansion, TSE, for describing the transient state. The parameter tgrav refers to a point in time where infiltration is dominated equally by capillarity and gravity as derived from the first two (dominant) terms of the TSE. Evidence suggests that applicability of the truncated two-term equation of Philip has a time limit requiring higher-order TSE terms to better describe the infiltration process for times exceeding that limit. Since the conceptual definition of tgrav is valid regardless of the infiltration model used, we opted to reformulate tgrav using the analytic implicit model proposed by Parlange et al. (1982), https://doi.org/10.1097/00010694-198206000-00001 valid for all times and related TSE. Our derived gravity times ensure a given accuracy of the approximations describing transient states, while also providing insight about the times needed to reach steady state. In addition to the roles of soil sorptivity (S) and the saturated (Ks) and initial (Ki) hydraulic conductivities, we explored the effects of a soil specific shape parameter β, involved in Parlange's model and related to the type of soil, on the behavior of tgrav. We show that the reformulated tgrav (notably (Formula presented.) where F(β) is a β-dependent function) is about three times larger than the classical tgrav given by (Formula presented.). The differences between the classical tgrav,Philip and the reformulated tgrav increase for fine-textured soils, attributed to the time needed to attain steady-state infiltration and thus i + nfiltration for inferring soil hydraulic properties. Results show that the proposed tgrav is a better indicator of time domain validity than tgrav,Philip. For the attainment of steady-state infiltration, the reformulated tgrav is suitable for coarse-textured soils. Still neither the reformulated tgrav nor the classical tgrav,Philip are suitable for fine-textured soils for which tgrav is too conservative and tgrav,Philip too short. Using tgrav will improve predictions of the soil hydraulic parameters (particularly Ks) from infiltration data compared to tgrav,Philip., Water Resources Research, 58 (5), ISSN:0043-1397, ISSN:1944-7973

Published
2022

35. How to Define the Appropriate Spatial Resolution of Root Segments When Solving in Root System Hydraulic

Author

UCL - SST/ELI/ELIA - Agronomy, UCL - SST/ELI/ELIE - Environmental Sciences, Meunier, Félicien, Couvreur, Valentin, Vanderborght, Jan, Javaux, Mathieu, UCL - SST/ELI/ELIA - Agronomy, UCL - SST/ELI/ELIE - Environmental Sciences, Meunier, Félicien, Couvreur, Valentin, Vanderborght, Jan, and Javaux, Mathieu

Abstract

In this chapter, we discuss the issue of balance between spatial resolution and computational efficiency in the context of the R-SWMS model. Based on the equations governing the water fluxes within the model, we propose here an objective and quantitative criterion which can help fix root segment size to both minimize computational load and achieve simulation according to a given accuracy degree.

Published
2022

36. Investigating Soil–Root Interactions with the Numerical Model R-SWMS

Author

UCL - SST/ELI/ELIA - Agronomy, UCL - SST/ELI/ELIE - Environmental Sciences, Meunier, Félicien, Couvreur, Valentin, Draye, Xavier, Lobet, Guillaume, Huber, Katrin, Schroeder, Nathalie, Jorda, Helena, Koch, Axelle, Landl, Magdalena, Schnepf, Andrea, Vanderborght, Jan, Vereecken, Harry, Javaux, Mathieu, UCL - SST/ELI/ELIA - Agronomy, UCL - SST/ELI/ELIE - Environmental Sciences, Meunier, Félicien, Couvreur, Valentin, Draye, Xavier, Lobet, Guillaume, Huber, Katrin, Schroeder, Nathalie, Jorda, Helena, Koch, Axelle, Landl, Magdalena, Schnepf, Andrea, Vanderborght, Jan, Vereecken, Harry, and Javaux, Mathieu

Abstract

In this chapter, we present the Root and Soil Water Movement and Solute transport model R-SWMS, which can be used to simulate flow and transport in the soil–plant system. The equations describing water flow in soil–root systems are presented and numerical solutions are provided. An application of R-SWMS is then briefly discussed, in which we combine in vivo and in silico experiments in order to decrypt water flow in the soil–root domain. More precisely, light transmission imaging experiments were conducted to generate data that can serve as input for the R-SWMS model. These data include the root system architecture, the soil hydraulic properties and the environmental conditions (initial soil water content and boundary conditions, BC). Root hydraulic properties were not acquired experimentally, but set to theoretical values found in the literature. In order to validate the results obtained by the model, the simulated and experimental water content distributions were compared. The model was then used to estimate variables that were not experimentally accessible, such as the actual root water uptake distribution and xylem water potential.

Published
2022

37. From soil-root hydraulic architectures to macroscopic representations of hydraulics in land surface models

Author

UCL - SST/ELI/ELIA - Agronomy, Vanderborght, Jan, Couvreur, Valentin, Meunier, Félicien, Bouda, Martin, Schnepf, Andrea, Javaux, Mathieu, UCL - SST/ELI/ELIA - Agronomy, Vanderborght, Jan, Couvreur, Valentin, Meunier, Félicien, Bouda, Martin, Schnepf, Andrea, and Javaux, Mathieu

Abstract

Root water uptake is an important process in the terrestrial water cycle. How this process depends on soil water content, root distributions, and root properties is a soil root hydraulic problem. We compare different approaches to implement root hydraulics in macroscopic soil water flow and land surface models. By upscaling a three-dimensional hydraulic root architecture model, we derived an exact macroscopic root hydraulic model. The macroscopic model uses the following three characteristics: the root system conductance, Krs, the standard uptake fraction, SUF, which represents the uptake from a soil profile with a uniform hydraulic head, and a compensatory matrix that describes the redistribution of water uptake in a non-uniform hydraulic head profile. The two characteristics, Krs and SUF, are sufficient to describe the total uptake as a function of the collar and soil water potential, and water uptake redistribution does not depend on the total uptake or collar water potential. We compared the exact model with two hydraulic root models that make a priori simplifications of the hydraulic root architecture, i.e., the parallel and big root model. The parallel root model uses only two characteristics, Krs and SUF, which can be calculated directly following a bottom-up approach from the 3D hydraulic root architecture. The big root model uses more parameters than the parallel root model, but these parameters cannot be obtained straightforwardly with a bottomup approach. The big root model was parameterized using a top-down approach, i.e., directly from root segment hydraulic properties, assuming a priori a single big root architecture. This simplification of the hydraulic root architecture led to less accurate descriptions of root water uptake than by the parallel root model. To compute root water uptake in macroscopic soil water flow and land surface models, we recommend the use of the parallel root model with Krs and SUF computed in a bottom-up approach from a known 3

Published
2022

38. Development and Validation of a Deep Learning Based Automated Minirhizotron Image Analysis Pipeline

Author

UCL - SST/ELI/ELIA - Agronomy, Bauer, Felix Maximilian, Lärm, Lena, Morandage, Shehan, Lobet, Guillaume, Vanderborght, Jan, Vereecken, Harry, Schnepf, Andrea, UCL - SST/ELI/ELIA - Agronomy, Bauer, Felix Maximilian, Lärm, Lena, Morandage, Shehan, Lobet, Guillaume, Vanderborght, Jan, Vereecken, Harry, and Schnepf, Andrea

Abstract

Root systems of crops play a significant role in agro-ecosystems. The root system is essential for water and nutrient uptake, plant stability, symbiosis with microbes and a good soil structure. Minirhizotrons, consisting of transparent tubes that create windows into the soil, have shown to be effective to non-invasively investigate the root system. Root traits, like root length observed around the tubes of minirhizotron, can therefore be obtained throughout the crop growing season. Analyzing datasets from minirhizotrons using common manual annotation methods, with conventional software tools, are time consuming and labor intensive. Therefore, an objective method for high throughput image analysis that provides data for field root-phenotyping is necessary. In this study we developed a pipeline combining state-of-the-art software tools, using deep neural networks and automated feature extraction. This pipeline consists of two major components and was applied to large root image datasets from minirhizotrons. First, a segmentation by a neural network model, trained with a small image sample is performed. Training and segmentation are done using “Root-Painter”. Then, an automated feature extraction from the segments is carried out by “RhizoVision Explorer”. To validate the results of our automated analysis pipeline, a comparison of root length between manually annotated and automatically processed data was realized with more than 58,000 images. Mainly the results show a high correlation (R=0.81) between manually and automatically determined root lengths. With respect to the processing time, our new pipeline outperforms manual annotation by 98.1 - 99.6 %. Our pipeline,combining state-of-the-art software tools, significantly reduces the processing time for minirhizotron images. Thus, image analysis is no longer the bottle-neck in high throughput phenotyping approaches.

Published
2022

39. Soil hydrology in the Earth system

Author

UCL - SST/ELI/ELIE - Environmental Sciences, Vereecken, Harry, Amelung, Wulf, Bauke, Sara L., Bogena, Heye, Brüggemann, Nicolas, Montzka, Carsten, Vanderborght, Jan, Bechtold, Michel, Blöschl, Günter, Carminati, Andrea, Javaux, Mathieu, Konings, Alexandra G., Kusche, Jürgen, Neuweiler, Insa, Or, Dani, Steele-Dunne, Susan, Verhoef, Anne, Young, Michael, Zhang, Yonggen, UCL - SST/ELI/ELIE - Environmental Sciences, Vereecken, Harry, Amelung, Wulf, Bauke, Sara L., Bogena, Heye, Brüggemann, Nicolas, Montzka, Carsten, Vanderborght, Jan, Bechtold, Michel, Blöschl, Günter, Carminati, Andrea, Javaux, Mathieu, Konings, Alexandra G., Kusche, Jürgen, Neuweiler, Insa, Or, Dani, Steele-Dunne, Susan, Verhoef, Anne, Young, Michael, and Zhang, Yonggen

Abstract

Soil hydrological processes (SHP) support ecosystems, modulate the impact of climate change on terrestrial systems and control feedback mechanisms between water, energy and biogeochemical cycles. However, land-use changes and extreme events are increasingly impacting these processes. In this Review, we describe SHP across scales and examine their links with soil properties, ecosystem processes and climate. Soil structure influences SHP such as infiltration, soil water redistribution and root water uptake on small scales. On local scales, SHP are driven by root water uptake, vegetation and groundwater dynamics. Regionally, SHP are impacted by extreme events such as droughts, floods, heatwaves and land-use change; however, antecedent and current SHP partially determine the broader effects of extreme events. Emerging technologies such as wireless and automated sensing, soil moisture observation through novel synthetic aperture radars satellites, big data analysis and machine learning approaches offer unique opportunities to advance soil hydrology. These advances, in tandem with the inclusion of more key soil types and properties in models, will be pivotal in predicting the role of SHP during global change.

Published
2022

40. Field scale plant water relation of maize (Zea mays) under drought – impact of root hairs and soil texture

Author

UCL - SST/ELI/ELIE - Environmental Sciences, Jorda, Helena, Ahmed, Mutez A., Javaux, Mathieu, Carminati, Andrea, Duddek, Patrick, Vetterlein, Doris, Vanderborght, Jan, UCL - SST/ELI/ELIE - Environmental Sciences, Jorda, Helena, Ahmed, Mutez A., Javaux, Mathieu, Carminati, Andrea, Duddek, Patrick, Vetterlein, Doris, and Vanderborght, Jan

Abstract

Background and aims Impact of drought on crop growth depends on soil and root hydraulic properties that determine the access of plant roots to soil water. Root hairs may increase the accessible water pool but their effect depends on soil hydraulic properties and adaptions of root systems to drought. These adaptions are difficult to investigate in pot experiments that focus on juvenile plants. Methods A wild-type and its root hairless mutant maize (Zea mays) were grown in the field in loam and sand substrates during two growing seasons with a large precipitation deficit. A comprehensive dataset of soil and plant properties and monitored variables were collected and interpreted using simulations with a mechanistic root water uptake model. Results Total crop water use was similar in both soils and for both genotypes whereas shoot biomass was larger for the wild type than for the hairless mutant and did not differ between soils. Total final root length was larger in sand than in loam but did not differ between genotypes. Simulations showed that root systems of both genotypes and in both soils extracted all plant available soil water, which was similar for sand and loam, at a potential rate. Leaf water potentials were overestimated by the model, especially for the hairless mutant in sand substrate because the water potential drop in the rhizosphere was not considered. Conclusions A direct effect of root hairs on water uptake was not observed but root hairs might influence leaf water potential dependent growth.

Published
2022

41. Response of a grassland species to dry environmental conditions from water stable isotopic monitoring: no evident shift in root water uptake to wetter soil layers

Author

UCL - SST/ELI/ELIE - Environmental Sciences, Deseano Diaz, Paulina Alejandra, van Dusschoten, Dagmar, Kübert, Angelika, Brüggemann, Nicolas, Javaux, Mathieu, Merz, Steffen, Vanderborght, Jan, Vereecken, Harry, Dubbert, Maren, Rothfuss, Youri, UCL - SST/ELI/ELIE - Environmental Sciences, Deseano Diaz, Paulina Alejandra, van Dusschoten, Dagmar, Kübert, Angelika, Brüggemann, Nicolas, Javaux, Mathieu, Merz, Steffen, Vanderborght, Jan, Vereecken, Harry, Dubbert, Maren, and Rothfuss, Youri

Abstract

Aims We aimed at assessing the influence of above- and below-ground environmental conditions over the performance of Centaurea jacea L., a drought-resistant grassland forb species. Methods Transpiration rate, CO2 assimilation rate, leaf water potential, instantaneous and intrinsic water use efficiency, temperature, relative humidity, vapor pressure deficit and soil water content in one plant and root length density in four plants, all grown in custom-made columns, were monitored daily for 87 days in the lab. The soil water isotopic composition in eleven depths was recorded daily in a non-destructive manner. The isotopic composition of plant transpiration was inferred from gas chamber measurements. Vertical isotopic gradients in the soil column were created by adding labeled water. Daily root water uptake (RWU) profiles were computed using the multi-source mixing model Stable Isotope Analysis in R (Parnell et al. PLoS ONE 5(3):1–5, 2010). Results RWU occurred mainly in soil layer 0–15 cm, ranging from 79 to 44%, even when water was more easily available in deeper layers. In wet soil, the transpiration rate was driven mainly by vapor pressure deficit and light intensity. Once soil water content was less than 0.12 cm3 cm− 3, the computed canopy conductance declined, which restricted leaf gas exchange. Leaf water potential dropped steeply to around − 3 MPa after soil water content was below 0.10 cm3 cm− 3. Conclusion Our comprehensive data set contributes to a better understanding of the effects of drought on a grassland species and the limits of its acclimation in dry conditions.

Published
2022

42. On Infiltration and Infiltration Characteristic Times

Author

Hydrogeology, Environmental hydrogeology, Rahmati, Mehdi, Latorre, Borja, Moret‐Fernández, David, Lassabatere, Laurent, Talebian, Nima, Miller, Dane, Morbidelli, Renato, Iovino, Massimo, Bagarello, Vincenzo, Neyshabouri, Mohammad Reza, Zhao, Ying, Vanderborght, Jan, Weihermüller, Lutz, Jaramillo, Rafael Angulo, Or, Dani, Genuchten, Martinus van, Vereecken, Harry, Hydrogeology, Environmental hydrogeology, Rahmati, Mehdi, Latorre, Borja, Moret‐Fernández, David, Lassabatere, Laurent, Talebian, Nima, Miller, Dane, Morbidelli, Renato, Iovino, Massimo, Bagarello, Vincenzo, Neyshabouri, Mohammad Reza, Zhao, Ying, Vanderborght, Jan, Weihermüller, Lutz, Jaramillo, Rafael Angulo, Or, Dani, Genuchten, Martinus van, and Vereecken, Harry

Published
2022

43. Same soil, different climate:Crop model intercomparison on translocated lysimeters

Author

Groh, Jannis, Diamantopoulos, Efstathios, Duan, Xiaohong, Ewert, Frank, Heinlein, Florian, Herbst, Michael, Holbak, Maja, Kamali, Bahareh, Kersebaum, Kurt‐Christian, Kuhnert, Matthias, Nendel, Claas, Priesack, Eckart, Steidl, Jörg, Sommer, Michael, Pütz, Thomas, Vanderborght, Jan, Vereecken, Harry, Wallor, Evelyn, Weber, Tobias K. D., Wegehenkel, Martin, Weihermüller, Lutz, Gerke, Horst H., Groh, Jannis, Diamantopoulos, Efstathios, Duan, Xiaohong, Ewert, Frank, Heinlein, Florian, Herbst, Michael, Holbak, Maja, Kamali, Bahareh, Kersebaum, Kurt‐Christian, Kuhnert, Matthias, Nendel, Claas, Priesack, Eckart, Steidl, Jörg, Sommer, Michael, Pütz, Thomas, Vanderborght, Jan, Vereecken, Harry, Wallor, Evelyn, Weber, Tobias K. D., Wegehenkel, Martin, Weihermüller, Lutz, and Gerke, Horst H.

Published
2022

44. Same soil, different climate: Crop model intercomparison on translocated lysimeters

Author

Groh, Jannis, primary, Diamantopoulos, Efstathios, additional, Duan, Xiaohong, additional, Ewert, Frank, additional, Heinlein, Florian, additional, Herbst, Michael, additional, Holbak, Maja, additional, Kamali, Bahareh, additional, Kersebaum, Kurt‐Christian, additional, Kuhnert, Matthias, additional, Nendel, Claas, additional, Priesack, Eckart, additional, Steidl, Jörg, additional, Sommer, Michael, additional, Pütz, Thomas, additional, Vanderborght, Jan, additional, Vereecken, Harry, additional, Wallor, Evelyn, additional, Weber, Tobias K. D., additional, Wegehenkel, Martin, additional, Weihermüller, Lutz, additional, and Gerke, Horst H., additional

Published
2022
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47. Loïc Pagès, founding scientist in root ecology and modelling

Author

Barczi, Jean-François, Beroueg, Amira, Buck-Sorlin, Gerhard, Couvreur, Valentin, Danjon, Frédéric, Delory, Benjamin M., Doussan, Claude, de Swaef, Tom, Draye, Xavier, Drouet, Jean-Louis, Dupuy, Lionel, Garre, Sarah, Gérard, Frédéric, Heymans, Adrien, Hinsinger, Philippe, Javaux, Mathieu, Koch, Axelle, Landl, Magdalena, Lecompte, François, Daniel, Leitner, Lobet, Guillaume, Lynch, Jonathan, Martre, Pierre, Meredieu, Céline, Meunier, Felicien, Mollier, Alain, Muller, Bertrand, Nguyen, Christophe, Picon-Cochard, Catherine, Postma, Johannes A., Pradal, Christophe, Rees, Frédéric, Richard-Molard, Céline, Roose, Tiina, Saint-Cast, Clément, Schnepf, Andrea, Thaler, Philippe, Vanderborght, Jan, Wu, Lianhai, Zhou, Xiaoran, Botanique et Modélisation de l'Architecture des Plantes et des Végétations (UMR AMAP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud])-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Unité de recherche Plantes et Systèmes de Culture Horticoles (PSH), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Institut de Recherche en Horticulture et Semences (IRHS), Université d'Angers (UA)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-INSTITUT AGRO Agrocampus Ouest, Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), Université Catholique de Louvain = Catholic University of Louvain (UCL), Biodiversité, Gènes & Communautés (BioGeCo), Université de Bordeaux (UB)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Leuphana University of Lüneburg, Environnement Méditerranéen et Modélisation des Agro-Hydrosystèmes (EMMAH), Avignon Université (AU)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Research Institute for Agricultural, Fisheries and Food (ILVO), Ecologie fonctionnelle et écotoxicologie des agroécosystèmes (ECOSYS), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Ikerbasque - Basque Foundation for Science, Ecologie fonctionnelle et biogéochimie des sols et des agro-écosystèmes (UMR Eco&Sols), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Institut de Recherche pour le Développement (IRD)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut Agro - Montpellier SupAgro, Forschungszentrum Jülich GmbH | Centre de recherche de Juliers, Helmholtz-Gemeinschaft = Helmholtz Association, Simulationswerkstatt, Pennsylvania State University (Penn State), Penn State System, Écophysiologie des Plantes sous Stress environnementaux (LEPSE), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut Agro - Montpellier SupAgro, Universiteit Gent = Ghent University (UGENT), Interactions Sol Plante Atmosphère (UMR ISPA), Ecole Nationale Supérieure des Sciences Agronomiques de Bordeaux-Aquitaine (Bordeaux Sciences Agro)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Unité Mixte de Recherche sur l'Ecosystème Prairial - UMR (UREP), VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Amélioration génétique et adaptation des plantes méditerranéennes et tropicales (UMR AGAP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut Agro - Montpellier SupAgro, Département Systèmes Biologiques (Cirad-BIOS), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad), University of Southampton, Département Performances des systèmes de production et de transformation tropicaux (Cirad-PERSYST), Rothamsted Research, Biotechnology and Biological Sciences Research Council (BBSRC), UCL - SST/ELI/ELIE - Environmental Sciences, and UCL - SST/ELI/ELIA - Agronomy

Subjects
0106 biological sciences, [SDV]Life Sciences [q-bio], 04 agricultural and veterinary sciences, Plant Science, Genetics and Molecular Biology (miscellaneous), 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biochemistry, Modeling and Simulation, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, ddc:004, Agronomy and Crop Science, ComputingMilieux_MISCELLANEOUS, 010606 plant biology & botany
Abstract

Root system scientists strive to understand how a single root, emerging from a plant’s seed, can form a complex, dynamic and plastic network of thousands of individual roots. They investigate how such a network is ideally suited to perform a number of functions required for the harmonious development of the whole plant. Everyone in the community also knows how complicated it can be to study root systems, with tasks ranging from digging plants out of the soil, creating experimental set-ups that allow the observation of the roots, to quantifying the root network itself or the processes underlying its formation. Within the community, there is one person, Dr Loïc Pagès, who has been working on all these tasks for many years, and who has moved the field forward numerous times. On the occasion of his soon-to-be retirement, we would like to express our appreciation to him via this editorial.

Published
2021

49. Isotopic composition of plant water sources

Author

Javaux, Mathieu, Rothfuss, Youri, Vanderborght, Jan, Vereecken, Harry, and Brggemann, Nicolas

Subjects
Isotopes -- Distribution, Water resources -- Environmental aspects -- Composition, Plants (Organisms) -- Environmental aspects, Company distribution practices, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Mathieu Javaux (corresponding author) [1, 2, 3]; Youri Rothfuss [1]; Jan Vanderborght [1]; Harry Vereecken [1]; Nicolas Brggemann [1] ARISING FROM J. Evaristo, S. Jasechko & J.J. McDonnell Nature [...]

Published
2016
Full Text
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50. A general approach for analytically upscaling the exact root water uptake equations despite heterogeneous soil moisture at the soil-root interface

Author

Bouda, Martin, Vanderborght, Jan, Javaux, Mathieu, EGU General Assembly 2021, and UCL - SST/ELI/ELIE - Environmental Sciences

Subjects
Root water uptake, Root system architecture, Soil-root interface, Interface (Java), Water uptake, Root (chord), Environmental science, Soil science, Water content, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics
Abstract

Recent advances in scaling up water flows on root system networks hold promise for improving predictions of water uptake at large scales. These developments are particularly timely, as persistent difficulties in getting Earth system models to accurately represent soil-root water flows, especially under drying or heterogeneous soil moisture conditions, are now a major obstacle describing the water limitation of terrestrial fluxes.One recently developed upscaling formalism has been shown to be both free of discretisation error in flow predictions regardless of scale and with computational cost linearly diminishing with the number of soil subdomains considered. What has been missing from this approach, however, is a proven method to apply it generally – i.e. to an arbitrary root system architecture discretised on an arbitrary grid.The work presented here demonstrates a general algorithm that can be applied to a wide range of root system architectures (the only assumption being that only one lateral root originates at one point along a parent root) discretised on a grid consisting of a series of soil layers of variable thickness, as is common in Earth system models. It is further shown theoretically that both of these restrictions can in principle be relaxed and that this approach can in principle be extended to conditions of soil moisture heterogeneity – i.e. situations where each root segment in a soil grid cell faces a different water potential at the soil-root interface.This work represents both a practical advance bringing broad applicability to this upscaling approach and a major theoretical advance as exact solutions for water uptake under conditions of soil moisture heterogeneity within grid cells were previously unknown. While obtaining exact solutions despite heterogeneity within the grid cell requires a way of finding the overall mean soil water potential faced by the plant, this advance nevertheless points to possible directions of future research for overcoming the major hurdle of soil moisture heterogeneity.

Published
2021

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