Extent and persistence of water repellency in two Iranian soils

Soil water repellency (SWR) can affect the hydrophysical properties of soils. The objective of this study was to evaluate a new approach, which allows estimating both the extent (the modified soil water repellency index, RI_m) and persistence (the water repellency cessation time, WRCT) of water repellency from a single measurement of the combined infiltration of water against time. The measurements were carried out on wettable and water repellent soil samples from 0-60 cm depth. Combined soil water repellency index, RI_c, was estimated from all the water and ethanol sorptivity values. The persistence of water repellency in soil aggregates (about 20 mm × 20 mm × 20 mm in size) was measured with the water drop penetration time (WDPT) test on both the field-moist aggregates (actual WDPT, A-WDPT) and aggregates dried at 65-70°C for 24 hours (potential WDPT, P-WDPT). In comparison with the wettable soil, hydrophysical parameters of the repellent soil were significantly different at the upper part of the profile (0-40 cm, P < 0.01), what can be attributed to the differences in organic matter content in both soils. Maximum organic matter (OM) content of the repellent soil was observed at the depth of 30-40 cm. Curiously, an insignificant difference between the studied soils was found in the saturated hydraulic conductivity, K_s. The mean values of A-WDPT and P-WDPT for water repellent soil were 438-and 106-Times greater than those for wettable soil, respectively. All the water and ethanol sorptivities (S_w, S_e, S_ww, and S_wh) were significantly (P < 0.01) greater in the wettable soil than those in the water repellent soil. The repellency indices RI_c and RI_m in water repellent soil were about seven-and two-Times higher than those in the wettable soil, respectively. Our findings pointed out the proposed method to estimate SWR can be used as a new approach. Considering that the contact angle (CA) of soil and water intrinsically depends on sorptivity state, it is suggested that the relation of CA and RI_m is investigated to find reference classes for WRCT and RI_m (i.e. WDPT > 5 s) and to classify water repellency states of soils.