Location: Soil Drainage Research
Title: Application of GPS and Near-Surface Geophysical Methods to Evaluate Agricultural Test Plot Differences Authors
|Clevenger, Bruce -|
|Saraswat, Dharmendra -|
Submitted to: Fast Times: News for the Near Surface Geophysical Sciences
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: September 7, 2009
Publication Date: September 9, 2009
Citation: Allred, B.J., Clevenger, B., Saraswat, D. 2009. Application of GPS and Near-Surface Geophysical Methods to Evaluate Agricultural Test Plot Differences. Fast Times: News for the Near Surface Geophysical Sciences. 14(3):15-24. Interpretive Summary: Characterization of the spatial differences in soil properties is important for cropping management decisions by farmers and for correctly interpreting the outcome of research trials conducted on the soil. New sensing technologies linked with global positioning system satellite information can provide precise knowledge of the soil properties and how they change over short distances. Adoption of this approach and technology proved to be a useful combination for delineating test plot differences at a field research facility including topography, subsurface drainage pipe location, and bulk electrical conductivity of the soil. This investigation serves as a very good example of how linked global position information and near-surface geophysical methods can be successfully employed to better characterize a farm field and avoid confounding of research trials.
Technical Abstract: A field research facility with two pairs of replicated agricultural test plots (four total) was established at a location in northwest Ohio during 2005 for the purpose of studying water table management strategies. Initial efforts at this field research facility were devoted to evaluating differences between replicated test plots in regard to topography, subsurface drainage system characteristics, and soil properties. Real-time kinematic (RTK) global positioning system (GPS) receivers along with ground penetrating radar and resistivity geophysical methods were employed to accomplish this task. Real-time kinematic GPS was used to map topography, while also determining coordinates for soil sampling locations and some geophysics measurement locations. Ground penetrating radar geophysical methods were employed to assess differences in subsurface drainage system characteristics. Spatial variations in soil properties were gauged by mapping apparent soil electrical conductivity with resistivity methods. The RTK-GPS topographic survey found an elevation difference of 1 m to exist across the four test plots. The ground penetrating radar survey found a 0.25 m dissimilarity in drainage pipe placement depth between two of the replicated test plots. Resistivity methods clearly showed differences between replicated test plots with respect to average apparent soil electrical conductivity values and the spatial patterns of apparent soil electrical conductivity. However, cone penetrometer readings and soil sample physical/chemical property data indicate that the apparent soil electrical conductivity response is itself governed by complex interactions of several soil properties. Overall, the GPS and near-surface geophysical information obtained at this site provided valuable insight on test plot dissimilarities that may affect differences in the hydrologic response between replicated test plots.