Comparing the EM38DD and DUALEM‐21S Sensors for Depth‐to‐Clay Mapping

Saey, Timothy; Simpson, David G.; Vermeersch, Hans; Cockx, Liesbet; Meirvenne, Marc Van

doi:10.2136/sssaj2008.0079

Cited by 112 publications

(67 citation statements)

References 20 publications

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“…Each of the aforementioned sensors has distinct operational advantages and disadvantages (Sudduth et al, 2003). Comparative studies have generally revealed close similarities between EC a data collected with different sensors (Doolittle et al, 2001(Doolittle et al, , 2002aSaey et al, 2009a;Sudduth et al, 1999Sudduth et al, , 2003Urdanoz and Aragüés, 2012). However, differences in sensor calibration, depth sensitivity and volume of soil material measured will affect measurements and result in slightly different EC a values.…”

Section: Emi Sensorsmentioning

confidence: 99%

The use of electromagnetic induction techniques in soils studies

Doolittle¹,

2014

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Section: Emi Sensorsmentioning

confidence: 99%

The use of electromagnetic induction techniques in soils studies

Doolittle¹,

2014

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“…In this study the apparent soil electric conductivity (ECa), was carried out by electromagnetic induction (EMI) sensors, which represents a very useful tool for identifying soil map units and soil properties in respect of clay content (Morari et al, 2009), soil depth (Saey et al, 2009), water content (Davies, 2004;Cousin et al, 2009;Lück et al, 2009;Tromp-van Meerveld and McDonnell, 2009) and water salinity (Doolittle et al, 2001).…”

Section: Pedological Survey and Soil Measurementsmentioning

confidence: 99%

Functional homogeneous zones (fHZs) in viticultural zoning procedure: an Italian case study on Aglianico vine

Bonfante

Agrillo

Albrizio

et al. 2015

SOIL

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Abstract. This paper aims to test a new physically oriented approach to viticulture zoning at farm scale that is strongly rooted in hydropedology and aims to achieve a better use of environmental features with respect to plant requirements and wine production. The physics of our approach are defined by the use of soil-plant-atmosphere simulation models, applying physically based equations to describe the soil hydrological processes and solve soil-plant water status.This study (part of the ZOVISA project) was conducted on a farm devoted to production of high-quality wines (Aglianico DOC), located in southern Italy (Campania region, Mirabella Eclano, AV). The soil spatial distribution was obtained after standard soil survey informed by geophysical survey. Two homogeneous zones (HZs) were identified; in each one a physically based model was applied to solve the soil water balance and estimate the soil functional behaviour (crop water stress index, CWSI) defining the functional homogeneous zones (fHZs). For the second process, experimental plots were established and monitored for investigating soil-plant water status, crop development (biometric and physiological parameters) and daily climate variables (temperature, solar radiation, rainfall, wind).The effects of crop water status on crop response over must and wine quality were then evaluated in the fHZs. This was performed by comparing crop water stress with (i) crop physiological measurement (leaf gas exchange, chlorophyll a fluorescence, leaf water potential, chlorophyll content, leaf area index (LAI) measurement), (ii) grape bunches measurements (berry weight, sugar content, titratable acidity, etc.) and (iii) wine quality (aromatic response). This experiment proved the usefulness of the physically based approach, also in the case of mapping viticulture microzoning.

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“…Examples of the application of EMI-based ECa measurements include soil salinity (e.g., Doolittle et al, 2001;Heilig et al, 2011), spatial patterns of soil texture (e.g., Abdu et al, 2008;Heil and Schmidhalter, 2012), lateral boundaries between soil types (e.g., Anderson-Cook et al, 2002;James et al, 2003), depth of clay-rich layers (e.g., Saey et al, 2009;Doolittle at al., 1994), clay content (e.g., King et al, 2005;Weller et al, 2007), soil compaction (e.g., Al-Gaadi, 2012;Islam et al, 2014), soil CEC (e.g., Headley et al, 2004;Triantafilis et al, 2009), soil organic carbon (e.g., Martinez et al, 2009;Altdorff et al, 2016), assessment of soil quality (e.g., Johnson et al, 2001;Corwin and Lesch, 2005), detection of buried services (e.g., Won and Huang, 2004;El-Quady et al, 2014), and mapping of active layer thickness in permafrost areas (e.g., Hauck and Kneisel, 2008;Dafflon et al, 2013). ECa measurements are widely used in the context of precision agriculture for, e.g., refining existing soil maps (e.g., Doolittle et al, 2008;Martini et al, 2013), precision farming (e.g., Lück et al, 2009;Scudiero et al, 2015), and harvest zoning (e.g., Frogbrook and Oliver, 2007;Priori et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Repeated electromagnetic induction measurements for mapping soil moisture at the field scale: validation with data from a wireless soil moisture monitoring network

Martini

Werban

Zacharias

et al. 2017

Hydrol. Earth Syst. Sci.

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Abstract. Electromagnetic induction (EMI) measurements are widely used for soil mapping, as they allow fast and relatively low-cost surveys of soil apparent electrical conductivity (ECa). Although the use of non-invasive EMI for imaging spatial soil properties is very attractive, the dependence of ECa on several factors challenges any interpretation with respect to individual soil properties or states such as soil moisture (θ ). The major aim of this study was to further investigate the potential of repeated EMI measurements to map θ , with particular focus on the temporal variability of the spatial patterns of ECa and θ . To this end, we compared repeated EMI measurements with high-resolution θ data from a wireless soil moisture and soil temperature monitoring network for an extensively managed hillslope area for which soil properties and θ dynamics are known. For the investigated site, (i) ECa showed small temporal variations whereas θ varied from very dry to almost saturation, (ii) temporal changes of the spatial pattern of ECa differed from those of the spatial pattern of θ , and (iii) the ECa-θ relationship varied with time. Results suggest that (i) depending upon site characteristics, stable soil properties can be the major control of ECa measured with EMI, and (ii) for soils with low clay content, the influence of θ on ECa may be confounded by changes of the electrical conductivity of the soil solution. Further, this study discusses the complex interplay between factors controlling ECa and θ , and the use of EMI-based ECa data with respect to hydrological applications.

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Comparing the EM38DD and DUALEM‐21S Sensors for Depth‐to‐Clay Mapping

Cited by 112 publications

References 20 publications

The use of electromagnetic induction techniques in soils studies

The use of electromagnetic induction techniques in soils studies

Functional homogeneous zones (fHZs) in viticultural zoning procedure: an Italian case study on Aglianico vine

Repeated electromagnetic induction measurements for mapping soil moisture at the field scale: validation with data from a wireless soil moisture monitoring network

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