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RESEARCH ARTICLE
Contents Vol 14(4)

Microbial recolonization and chemical changes in a soil heated at different temperatures

César Guerrero A B , Jorge Mataix-Solera A , Ignacio Gómez A , Fuensanta García-Orenes A and Manuel M. Jordán A
+ Author Affiliations
- Author Affiliations

A Grupo de Edafología Ambiental, Departamento de Agroquímica y Medio Ambiente, Universidad Miguel Hernández, Avenida de la Universidad s/n 03202, Elche, Alicante, Spain.

B Corresponding author. Telephone: +34 966658333; fax: +34 966658340; email: cesar.guerrero@umh.es

International Journal of Wildland Fire 14(4) 385-400 https://doi.org/10.1071/WF05039
Submitted: 31 March 2005  Accepted: 9 September 2005   Published: 25 November 2005

Abstract

Samples of a Mediterranean forest soil were exposed in a muffle furnace to seven temperatures (100–700°C) for 15 min to simulate different fire intensities. Heated soils were incubated for 100 days after re-inoculation with fresh unheated soil. Immediately after heating, the extractable organic C increased with the heating temperature, reaching a maximum at 400°C. This increase in extractable organic C and nutrients in soils heated below 400°C allowed a rapid recolonization of bacteria, increasing the basal respiration. During the 100-day incubation, the cumulative values of basal respiration and carbon mineralization rates generally followed a double exponential equation in unheated and heated samples. Heating at 200°C caused a reduction of 99.6% for fungi (measured as culturable fungal propagules), which showed lower recolonization capacity than that of bacteria. Heating also caused a decrease in the organic C content of the soils, especially for the highest temperatures. As a consequence, the microbial biomass carbon recovery was short lived in heated soils. The varied effects of heating and incubation on the inorganic and organic nitrogen changes, available nutrients and metabolic quotients are also discussed. This study demonstrates that changes in soils exposed to comparatively high temperatures (>500°C) have a particularly strong impact on microbial population.

Additional keywords: incubation; metabolic quotient; microbial biomass; microorganisms; respiration.


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