Bayad, MChau, HenryTrolove, SMoir, JamesCondron, LBouray, M2021-01-132020-08-192020-092020-08-142073-4441OD7RD (isidoc)https://hdl.handle.net/10182/13210In this work, we modelled the response of soil water repellency (SWR) persistence to the decrease in moisture in drying soils, and we explored the implication of soil particle size distribution and specific surface area on the SWR severity and persistence. A new equation for the relationship between SWR persistence and soil moisture (θ) is described in this paper. The persistence of SWR was measured on ten different hydrophobic soils using water drop penetration time (WDPT) at decreasing levels of gravimetric water content. The actual repellency persistence showed a sigmoidal response to soil moisture decrease, where Rₐ(θ) = Rₚ/1 + eδ⁽θ⁻θ𝒸⁾. The suggested equation enables one to model the actual SWR persistence (Rₐ) using θ, the potential repellency (Rₚ) and two characteristic parameters related to the shape of the response curve. The two parameters are the critical soil moisture θ𝒸, where the Rₐ increase rate reaches its maximum, and the parameter δ affecting the steepness of the curve at the inflexion point of the sigmoidal curve. Data shows that both soil carbon and texture are controlling the potential SWR in New Zealand pastures.12 pagesen© 2020 by the authors. Licensee MDPI, Basel, Switzerland.soil water repellencysoil moisturesoil carbonsoil textureJournal Article10.3390/W12092322ANZSRC::0503 Soil SciencesANZSRC::080110 Simulation and ModellingANZSRC::070104 Agricultural Spatial Analysis and ModellingANZSRC::079901 Agricultural Hydrology (Drainage, Flooding, Irrigation, Quality, etc.)ANZSRC::05 Environmental Sciences2073-4441https://creativecommons.org/licenses/by/4.0/Attribution