Heat-induced alterations in moisture-dependent repellency of water-repellent forest soils: A laboratory approach with Japanese Andosols

Soil water repellency (SWR) is a phenomenon that prevents the spontaneous wetting of numerous forest soils. It is a moisture-dependent characteristic, which disappears when soil moisture reaches near saturation. The heat generated during forest fires affects soil characteristics including SWR. The p...

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Bibliographic Details
Published in:Journal of Hydrology and Hydromechanics 2024-03, Vol.72 (1), p.25-33
Main Authors: Perera, H.T.M., Mori, Yasushi, Maeda, Morihiro, Leelamanie, D.A.L.
Format: Article
Language:English
Subjects:
Drying
Forest fires
Forest soils
Forests
Heat
Heat treatment
Heat treatments
High temperature
Hydrophobicity
Japanese Andosols
Laboratory heating
Moisture content
Moisture-dependent repellency
Pest control
Repellency
Repellents
Saturation
Soil
Soil characteristics
Soil investigations
Soil moisture
Soil temperature
Soil testing
Soil types
Soil water
Soil water repellency
Temperature effects
Water
Water content
Water droplets
Water drops
Water repellent soils
Wildfires
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Summary:Soil water repellency (SWR) is a phenomenon that prevents the spontaneous wetting of numerous forest soils. It is a moisture-dependent characteristic, which disappears when soil moisture reaches near saturation. The heat generated during forest fires affects soil characteristics including SWR. The possibility of heat influencing moisture-dependent repellency (MDR) is not well understood. The present study aimed to investigate the effects of different heating temperatures (H ) and exposure durations (E ) on MDR using water-repellent Japanese Cedar (CED) and Japanese Cypress (CYP) forest soils. Soil samples collected from 0–5 cm depth were exposed to heat separately at 50, 100, and 150 °C ( ) for 1 h and 2 h durations ( ). The MDR of heated and non-heated soils was determined using the water drop penetration time (WDPT) test in a drying process. During the drying process of the tested soils, SWR appeared and then increased with drying to reach an extreme level (WDPT ≥3600 s) that persisted for a range of decreasing moisture contents, and declined to be non-repellent again (WDPT = 0 s). The critical moisture content at which soils become water-repellent with drying (CMC), the highest and the lowest moisture contents when soils showed maximum SWR (HMC and LMCmax, respectively), and the integrated area below the MDR curve (S ) decreased with increasing H in both CED and CYP soils. The moisture content at which soils become non-repellent again during drying, MCNR, was independent of the type of soil and heat treatment. The range of moisture contents between HMC and LMCmax, where soils show maximum SWR during drying, decreased with increasing HT, from 50 to 150 °C in CED and from 100–150 °C in CYP. The SWR showed strong positive linear correlations with CMC and HMC . The heat generated during wildfires can alter the MDR and all the related repellency parameters of water-repellent forest soils. SWR prevails over a narrower range of moisture contents in heated soil compared with non-heated soils. Further investigations with higher temperature levels using different soil types would be important for a comprehensive understanding of the heat impacts on MDR.
ISSN:1338-4333
0042-790X
1338-4333
DOI:10.2478/johh-2023-0035