Impact of olive mill wastewater (OMW) on the soil hydraulic and solute transport properties

Comegna, Alessandro; Dragonetti, Giovanna; Kodešová, Radka; Coppola, Antonio

doi:10.1007/s13762-021-03630-6

Cited by 9 publications

(5 citation statements)

References 70 publications

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“…Figure 10a,b illustrate the θ(h) and K(θ) relationship at the reference depth z 4 ; K values were determined via the IPM method using Equation (4). The empirical retention model by van Genuchten [56] and van Genuchten integrated with the Mualem [57] expression were used to predict, respectively, the experimental θ(h) and K(θ) functions.…”

Section: Shyprom Laboratory Testingmentioning

confidence: 99%

“…The soil unsaturated zone (or the vadose zone) is the connection zone between the atmosphere and the groundwater and, from a hydrological point of view, plays a fundamental role in the partition of precipitation between surface water, soil water and groundwater [1][2][3][4]. The amount of water that enters the soil is stored in the vadose zone and, from here, can be subjected to several hydrological processes that cause water to move within the soil profile.…”

Section: Introductionmentioning

confidence: 99%

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Development and Application of an IoT-Based System for Soil Water Status Monitoring in a Soil Profile

Comegna,

Hassan,

Coppola

2024

Sensors

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Soil water content (θ), matric potential (h) and hydraulic conductivity (K) are key parameters for hydrological and environmental processes. Several sensors have been developed for measuring soil θ–h–K relationships. The cost of such commercially available sensors may vary over several orders of magnitude. In recent years, some sensors have been designed in the framework of Internet of Things (i.e., IoT) systems to make remote real-time soil data acquisition more straightforward, enabling low-cost field-scale monitoring at high spatio-temporal scales. In this paper, we introduce a new multi-parameter sensor designed for the simultaneous estimation of θ and h at different soil depths and, due to the sensor’s specific layout, the soil hydraulic conductivity function via the instantaneous profile method (IPM). Our findings indicate that a second-order polynomial function is the most suitable model (R2 = 0.99) for capturing the behavior of the capacitive-based sensor in estimating θ in the examined soil, which has a silty-loam texture. The effectiveness of low-cost capacitive sensors, coupled with the IPM method, was confirmed as a viable alternative to time domain reflectometry (TDR) probes. Notably, the layout of the sensor makes the IPM method less labor-intensive to implement. The proposed monitoring system consistently demonstrated robust performance throughout extended periods of data acquisition and is highly suitable for ongoing monitoring of soil water status.

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Section: Shyprom Laboratory Testingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development and Application of an IoT-Based System for Soil Water Status Monitoring in a Soil Profile

Comegna,

Hassan,

Coppola

2024

Sensors

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“…In this paper, a novel fast soil hydraulic characterisation method called the TDR-2Dmod method, was used, which integrates time domain reflectometry (TDR) measurements and 2D transient modelling of the water content dynamics in the wetted bulb developing in the soil under a point-source (Coppola et al, 2022). TDR is a consolidated geophysical method for measuring soil water content and electrical conductivity in the same observation volume (Coppola et al, 2016;Dragonetti et al, 2018Dragonetti et al, , 2022Schaap et al, 2003), which has recently been applied also to monitor immiscible contaminants in natural (Comegna et al, 2013(Comegna et al, , 2017(Comegna et al, , 2022a and artificial (Belviso et al, 2022;Comegna et al, 2022b) porous media. In practice, the method consists of irrigating the soil with a dripper (the point source) and monitoring the water content dynamics in the wetted bulb in soil under the dripper by one or more TDR probes (Figure 2).…”

Section: Field Measurements Of Soil Hydraulic Propertiesmentioning

confidence: 99%

Comparing actual transpiration fluxes as measured at leaf-scale and calculated by a physically based agro-hydrological model

et al. 2023

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The main purpose of this paper is to compare the actual transpiration rates from tomato crop, as measured at leaf scale and estimated by a macroscopic approach in an agro-hydrological model, named FLOWS-HAGES, under variable soil properties and water availability. To this aim, sixteen plots were cultivated with tomatoes in Metaponto, Southern Italy. Soil hydraulic properties (SHP) were obtained using a fast in-situ characterization method. Leaf-area index (LAI) was measured using a leaf-area meter. SHP and LAI were then used in the physically-based FLOWS-HAGES which allowed calculating the macroscopic transpiration rates, Ta,m. Single-leaf transpiration rates, Ta,l, and stomatal conductance, gs,l, were measured in situ. For comparing with Ta,m, gs,l was upscaled by Big-Leaf approach to canopy scale stomatal conductance, gs,c, which was applied to Penman-Monteith model to obtain the canopy-scale transpiration, Ta,c. Finally, multiple linear regression (MLR) was used to find the statistical relationship between Ta,m and Ta,c, and the SHP and gs,c. Results showed that the macroscopic approach smooths the spatial variability of transpiration rates. Ta,c increased with the saturated water content, θs, and the slope of the water retention curve, n, while Ta,m decreased with increasing θs and n. MLR improved significantly by introducing gs,c to predict Ta,m.

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“…The RETC software package [53] was employed to determine van Genuchten's model parameters via a nonlinear least squares optimization approach [54]. In the RETC procedure, θ r is assumed to be zero.…”

Section: Hydrophysical Characterization Of the Soil-zeolite Mixturesmentioning

confidence: 99%

Impact of Zeolite from Coal Fly Ash on Soil Hydrophysical Properties and Plant Growth

et al. 2022

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Zeolites can be extensively employed in agricultural activities because they improve soil properties such as infiltration rates, saturated hydraulic conductivity, water holding capacity, and cation exchange capacity. Natural and synthetic zeolites can efficiently hold water. Zeolites are also believed to have the ability to lose and gain water reversibly, without changing their crystal structure. In the present study, several laboratory tests were carried out using: (i) zeolite synthesized from coal fly ash (a waste product from burning coal in thermoelectric power plants), (ii) a silty loam soil, typically found in Southern Italy, and (iii) sunflower as a reference plant. The selected soil was amended with different percentages of zeolite (1, 2, 5, and 10%) and the effects of the synthetic mineral addition on the hydrophysical properties of the soil and plant growth were evaluated. The results indicated that soil–zeolite mixtures retained water more efficiently by pore radius modification. However, this causes a variation in the range of plant-available water towards higher soil humidity values, as the amount of added zeolite increases. These data confirm that zeolite addition modifies the selected hydrophysical properties of the soil with the effect of decreasing the soil drainage capacity, making the soil less habitable for plant growth.

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Impact of olive mill wastewater (OMW) on the soil hydraulic and solute transport properties

Cited by 9 publications

References 70 publications

Development and Application of an IoT-Based System for Soil Water Status Monitoring in a Soil Profile

Development and Application of an IoT-Based System for Soil Water Status Monitoring in a Soil Profile

Comparing actual transpiration fluxes as measured at leaf-scale and calculated by a physically based agro-hydrological model

Impact of Zeolite from Coal Fly Ash on Soil Hydrophysical Properties and Plant Growth

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