A novel approach to estimate soil penetrometer resistance from water content, bulk density, and shear wave velocity: A laboratory study on a loamy sand soil.

• A simple model for penetrometer resistance is developed. • Input variables can be estimated from heat pulse and shear wave measurements. • Matric potential does not need to be measured to estimate penetrometer resistance. • Combined effects of compaction and drying are taken into account by the small strain shear modulus. • A method that could be used in the field is proposed. Continuous estimates of penetrometer resistance (Q) would be useful in root elongation and in soil management studies. However, penetrometers produce estimates of penetration resistance at discrete time points. In this paper, a method with the potential to provide continuous estimates of penetrometer resistance is developed. We use measurements of soil water content, shear wave velocity (V s) determined from piezo electric devices, and bulk density (ρ b) determined with the heat pulse (HP) method, to estimate penetrometer resistance. Soil samples of a loamy sand were packed into cylinders with axial pressures of 50, 100, and 200 kPa, and allowed to equilibrate at matric potentials of −2, −6, −10, −30, −100, −300, and −500 kPa. Thermal conductivity (λ), V s and Q were measured after equilibration. A λ -based approach was applied to estimate ρ b , and small strain shear modulus (G) was calculated from ρ b and V s. Our results confirmed a linear relationship between Q and G (where G = V s 2 ρ b), which provides a basis to estimate penetrometer data in the field using buried sensors and a physically based model. [ABSTRACT FROM AUTHOR]