Temperature-Corrected Calibration of GS3 and TEROS-12 Soil Water Content Sensors

Paolo Nasta; Francesca Coccia; Ugo Lazzaro; Heye R Bogena; Johan A Huisman; Benedetto Sica; Caterina Mazzitelli; Harry Vereecken; Nunzio Romano

doi:10.3390/s24030952

Temperature-Corrected Calibration of GS3 and TEROS-12 Soil Water Content Sensors

Sensors (Basel). 2024 Feb 1;24(3):952. doi: 10.3390/s24030952.

Authors

Paolo Nasta¹, Francesca Coccia¹, Ugo Lazzaro¹, Heye R Bogena², Johan A Huisman², Benedetto Sica¹, Caterina Mazzitelli¹, Harry Vereecken², Nunzio Romano¹

Affiliations

¹ Department of Agricultural Sciences, AFBE Division, University of Naples Federico II, 80055 Portici, Italy.
² Agrosphere Institute (IBG-3), Forschungszentrum Juelich GmbH, 52425 Juelich, Germany.

Abstract

The continuous monitoring of soil water content is commonly carried out using low-frequency capacitance sensors that require a site-specific calibration to relate sensor readings to apparent dielectric bulk permittivity (K_b) and soil water content (θ). In fine-textured soils, the conversion of K_b to θ is still challenging due to temperature effects on the bound water fraction associated with clay mineral surfaces, which is disregarded in factory calibrations. Here, a multi-point calibration approach accounts for temperature effects on two soils with medium to high clay content. A calibration strategy was developed using repacked soil samples in which the K_b-θ relationship was determined for temperature (T) steps from 10 to 40 °C. This approach was tested using the GS3 and TEROS-12 sensors (METER Group, Inc. Pullman, WA, USA; formerly Decagon Devices). K_b is influenced by T in both soils with contrasting T-K_b relationships. The measured data were fitted using a linear function θ = aKb + b with temperature-dependent coefficients a and b. The slope, a(T), and intercept, b(T), of the loam soil were different from the ones of the clay soil. The consideration of a temperature correction resulted in low RMSE values, ranging from 0.007 to 0.033 cm³ cm^-3, which were lower than the RMSE values obtained from factory calibration (0.046 to 0.11 cm³ cm^-3). However, each experiment was replicated only twice using two different sensors. Sensor-to-sensor variability effects were thus ignored in this study and will be systematically investigated in a future study. Finally, the applicability of the proposed calibration method was tested at two experimental sites. The spatial-average θ from a network of GS3 sensors based on the new calibration fairly agreed with the independent area-wide θ from the Cosmic Ray Neutron Sensor (CRNS). This study provided a temperature-corrected calibration to increase the accuracy of commercial sensors, especially under dry conditions, at two experimental sites.

Keywords: Cosmic Ray Neutron Sensor; capacitance sensors; sensor performance; soil apparent permittivity; soil temperature.

Grants and funding

This research was funded by the Ministry of Education and Merit with the PNRR-PRIN Project “Assessing and mapping novel agroecosystem vulnerability and resilience indicators in southern Italy—ASAP” (grant P20228L3KX).