Changes in water repellency, aggregation and organic matter of a mollic horizon burned in laboratory: Soil depth affected by fire

High variability in the literature is reported on the soil depth affected by forest fires because many factors are involved. We study the fire-induced changes on properties related to soil erodibility as water repellency (WR), soil aggregate stability (SAS) and organic matter at topsoil centimeter-s...

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Bibliographic Details
Published in:Geoderma 2014-01, Vol.213, p.400-407
Main Authors: Badía-Villas, David, González-Pérez, José A., Aznar, Javier M., Arjona-Gracia, Beatriz, Martí-Dalmau, Clara
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
Biological and medical sciences
Combustion
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fires
Forest fire
Forest fires
Fundamental and applied biological sciences. Psychology
Horizon
Outdoor
Pine
Py–GC/MS
Soil (material)
Soil aggregate stability
Soil organic carbon
Soils
Surficial geology
Topsoil
Topsoil depth
Wettability
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Summary:High variability in the literature is reported on the soil depth affected by forest fires because many factors are involved. We study the fire-induced changes on properties related to soil erodibility as water repellency (WR), soil aggregate stability (SAS) and organic matter at topsoil centimeter-scale (O horizon, and Ah horizon at 1, 2 and 3cm depth). In order to achieve this aim, topsoil monoliths (Rendzic Phaeozem) were sampled from an Aleppo pine forest, with no recent history of forest fires and burned in an outdoor combustion tunnel. Fire caused an immediate and significant decrease in WR, total organic carbon (TOC) and pyrolyzed carbon (PyC) in the O horizon. The Ah horizon was also affected by burning but only up to 2cm soil depth and with a different intensity according to the soil property: TOC was not significantly affected; WR and PyC decreased up to the upper centimeter and SAS up to 2cm Ah horizon depth. Soil burning involved the loss of 2/3 of the pre-fire TOC of the O horizon and 1/3 of the TOC of the upper centimeter of the Ah horizon. Fire also modified the structural composition of organic matter, an effect that was apparent again only above 2cm depth. Specifically the relative abundance of typical vegetation markers (terpenes, resinic acids) and lignin markers (methoxyphenols) decreased. Fire fragmented the long-chain molecules of the alkylic series (n-alkanes, alkenes, fatty acids and methylated fatty acids). This observation, together with a conspicuous reduction in the amount of organic molecules with functional groups in the upper centimeters of the soil monoliths, may be related to the fire-induced decreases in WR and SAS. In conclusion, moderate burning of a mollic horizon in the laboratory produced changes in the hydrophobicity, aggregation, and organic matter only up to 2cm depth. [Display omitted] •Fire produce: A decrease in WR, TOC and PyC in the O-horizon, A decrease in WR and PyC (up to 1cm of Ah) and SAS (up to 2cm), The elimination of almost all pyrosylates in the O-horizon and the 1st cm of Ah, The fragmentation of alkylic chains (specially alkenes) up to 2cm soil depth.•No changes are found below 2cm soil depth of the Ah mollic horizon due to fire.
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2013.08.038