What Can We Learn From the Water Retention Characteristic of a Soil Regarding Its Hydrological and Agricultural Functions? Review and Analysis of Actual Knowledge

Assouline, S.

doi:10.1029/2021wr031026

Cited by 17 publications

(12 citation statements)

References 84 publications

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“…The hysteresis phenomenon found in the relationships between the two plant water potentials: Ψ trunk vs. Ψ stem ( Figure 8A ), which was more noticeable for Ψ trunk vs. Ψ leaf ( Figure 8B ), was higher for the highest imposed soil water deficit (α=100%). This hysteretic behaviour revealed that the water status of the trunk assumes a dominant role in controlling canopy water status as water stress accumulates, which is related to plant hydraulic conductivity during the daily course ( Assouline, 2021 ). In addition, stomata reopened in the afternoon, as indicated by the recovery values of the diurnal pattern of leaf gas exchange ( Figures 9G–I ).…”

Section: Discussionmentioning

confidence: 99%

Assessment of trunk microtensiometer as a novel biosensor to continuously monitor plant water status in nectarine trees

Conesa

Conejero²,

Vera³

et al. 2023

Front. Plant Sci.

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The objective of this work was to validate the trunk water potential (Ψtrunk), using emerged microtensiometer devices, as a potential biosensor to ascertain plant water status in field-grown nectarine trees. During the summer of 2022, trees were subjected to different irrigation protocols based on maximum allowed depletion (MAD), automatically managed by real-time soil water content values measured by capacitance probes. Three percentages of depletion of available soil water (α) were imposed: (i) α=10% (MAD=27.5%); (ii) α=50% (MAD=21.5%); and (iii) α=100%, no-irrigation until Ψstem reached -2.0 MPa. Thereafter, irrigation was recovered to the maximum water requirement of the crop. Seasonal and diurnal patterns of indicators of water status in the soil-plant-atmosphere continuum (SPAC) were characterised, including air and soil water potentials, pressure chamber-derived stem (Ψstem) and leaf (Ψleaf) water potentials, and leaf gas exchange, together with Ψtrunk. Continuous measurements of Ψtrunk served as a promising indicator to determine plant water status. There was a strong linear relationship between Ψtrunkvs. Ψstem (R2 = 0.86, p<0.001), while it was not significant between Ψtrunkvs. Ψleaf (R2 = 0.37, p>0.05). A mean gradient of 0.3 and 1.8 MPa was observed between Ψtrunkvs.Ψstem and Ψleaf, respectively. In addition, Ψtrunk was the best matched to the soil matric potential. The main finding of this work points to the potential use of trunk microtensiometer as a valuable biosensor for monitoring the water status of nectarine trees. Also, trunk water potential agreed with the automated soil-based irrigation protocols implemented.

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Section: Discussionmentioning

confidence: 99%

Assessment of trunk microtensiometer as a novel biosensor to continuously monitor plant water status in nectarine trees

Conesa

Conejero²,

Vera³

et al. 2023

Front. Plant Sci.

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“…The measurement time is highly variable in each method, and a longer equilibration time is required as h becomes smaller (i.e., more negative). However, there is no single method to characterize a continuous water retention process across the full range of h (Assouline, 2021).…”

Section: Core Ideasmentioning

confidence: 99%

Automated hanging water column for characterizing water retention and hysteresis of coarse‐textured porous media

Dixon,

Blakeslee,

Mills

et al. 2023

Soil Science Soc of Amer J

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Modeling and characterizing hysteretic water retention is critical for predicting hydrodynamic behavior in porous media. This is especially true in coarse‐textured media used in geotechnical engineering, greenhouse, and landscape industries, where subtle changes in water status may lead to plant stress. However, based on the traditional hanging water column method, water retention measurements are laborious and time‐consuming because of the stepwise manual water potential adjustments and wait‐time requirements for equilibrium conditions to develop. Therefore, we designed and fabricated an automated system to collect wetting‐ and drying‐water retention data from coarse porous media. The basic system consistedThis article is protected by copyright. All rights reserved

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“…Soil water storage (SWS) and availability are two common indicators of soil hydrological function (Assouline, 2021), reflecting the ease of absorbing soil water for crops (Filho et al., 2013; Li et al., 2020). Plant available water (PAW) and least limiting water range (LLWR) are commonly applied to measure the soil water availability for plants from different angles (Asgarzadeh et al., 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Soil hydrological function is the result of the interaction of multiple soil properties, which makes it hard to analyze the effect of a single soil property on soil hydrological function (Assouline, 2021; Basche & DeLonge, 2017; Bayabil et al., 2019). Previous studies have shown that soil structure plays a vital role in soil hydrological function (Fei et al., 2019; Głąb et al., 2016).…”

Section: Introductionmentioning

confidence: 99%

Factors governing soil hydrological function under long‐term tillage practices: Insight into soil water repellency

Liu

et al. 2023

Soil Science Soc of Amer J

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Drought is increasingly common due to frequent occurrences of extreme weather events, which further increases soil water repellency (SWR). It could reinforce the effect of SWR on soil functions under conservation tillage systems. However, the relationship between SWR and soil hydrological function is still unclear. We studied the impacts of SWR and soil structure on soil hydrological function. Three treatments were conducted in a long-term tillage experiment: conventional tillage (CT), reduced tillage (RT), and no-tillage (NT). Tillage, soil depth, and growth period had significant influences on SWR, soil structure (i.e., penetration resistance [PR], total porosity [TP], and mean weight diameter [MWD]), and soil hydrological functions (i.e., water storage, least limiting water range [LLWR], and plant available water). Compared to CT, NT and RT increased the water repellency index (RI) in 0-20 cm by 13.8%-40.1% and 6.5%-18.2% during the growth period. RI played a prominent role in increasing soil water storage compared to soil TP, PR, MWD, and SOC. PR was the most critical influence on LLWR compared to other variables. A structural equation model revealed that SWR directly affected soil hydrological function, whereas the effect of SWR (0.24) was smaller than that of soil structure (0.67). In addition, soil structure had a direct influence on SWR, indicating that the effect of SWR could be regulated by soil structure. Overall, this study showed a link between SWR and soil hydrological function and provides deeper fundamental insights into the role of SWR on the sustainability of conservation tillage.

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What Can We Learn From the Water Retention Characteristic of a Soil Regarding Its Hydrological and Agricultural Functions? Review and Analysis of Actual Knowledge

Cited by 17 publications

References 84 publications

Assessment of trunk microtensiometer as a novel biosensor to continuously monitor plant water status in nectarine trees

Assessment of trunk microtensiometer as a novel biosensor to continuously monitor plant water status in nectarine trees

Automated hanging water column for characterizing water retention and hysteresis of coarse‐textured porous media

Factors governing soil hydrological function under long‐term tillage practices: Insight into soil water repellency

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