Abstract
Abstract. Fire is a major driver of soil organic matter (SOM) dynamics, and contemporary global climate change is changing global fire regimes. We conducted laboratory heating experiments on soils from five locations across the western Sierra Nevada climosequence to investigate thermal alteration of SOM properties and determine temperature thresholds for major shifts in SOM properties. Topsoils (0 to 5 cm depth) were exposed to a range of temperatures that are expected during prescribed and wild fires (150, 250, 350, 450, 550, and 650 °C). With increase in temperature, we found that the concentrations of carbon (C) and nitrogen (N) decreased in a similar pattern among all five soils that varied considerably in their original SOM concentrations and mineralogies. Soils were separated into discrete size classes by dry sieving. The C and N concentrations in the larger aggregate size fractions (2–0.25 mm) decreased with an increase in temperature, so that at 450 °C the remaining C and N were almost entirely associated with the smaller aggregate size fractions ( < 0.25 mm). We observed a general trend of 13C enrichment with temperature increase. There was also 15N enrichment with temperature increase, followed by 15N depletion when temperature increased beyond 350 °C. For all the measured variables, the largest physical, chemical, elemental, and isotopic changes occurred at the mid-intensity fire temperatures, i.e., 350 and 450 °C. The magnitude of the observed changes in SOM composition and distribution in three aggregate size classes, as well as the temperature thresholds for critical changes in physical and chemical properties of soils (such as specific surface area, pH, cation exchange capacity), suggest that transformation and loss of SOM are the principal responses in heated soils. Findings from this systematic investigation of soil and SOM response to heating are critical for predicting how soils are likely to be affected by future climate and fire regimes.
Highlights
Widespread global phenomenon (Bowman et al, 2009) that conditions the dynamics of soil and soil organic matter (SOM)
The initial concentration of C ranged from 1.5 % (Vista soil, 210 m) to 7.7 % (Musick soils, 1384 m)
Fourier transform infrared (FTIR) analyses from our work showed that the aliphatic O−H stretch peak disappeared at temperatures above 550 ◦C for all soils accompanied by nitriles or methane nitrile C≡N stretch (2300–2200 cm−1) at temperatures above 450 ◦C, suggesting condensation of aromatic functional groups
Summary
Widespread global phenomenon (Bowman et al, 2009) that conditions the dynamics of soil and soil organic matter (SOM). Vegetation fires burn an estimated 300 to 400 million ha of land globally every year (FAO, 2005). In the Sierra Nevada, vegetation fires have a major influence on the landscape. Ecological functions such as plant regeneration, habitat revitalization, biomass accumulation, and nutrient cycling are influenced by fires (McKelvey et al, 1996). Anthropogenic activities have become major causes of vegetation fires (Caldararo, 2002). Significant changes in global fire regimes are anticipated because of climate change, including increased frequency of fires in the coming decades
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