Abstract
Carbon-rich soils, like histosols or gelisols, cover more than 3% of the Earth's land surface, and store roughly three times more carbon than the Earth's forests. Carbon-rich soils are reactive porous materials, prone to smouldering combustion if the inert and moisture contents are low enough. An example of soil combustion happens in peatlands, where smouldering wildfires are common in both boreal and tropical regions. This work focuses on understanding soil ignition by self-heating, which is due to spontaneous exothermic reactions in the presence of oxygen under certain thermal conditions. We investigate the effect of soil inorganic content by creating under controlled conditions soil samples with inorganic content (IC) ranging from 3% to 86% of dry weight: we use sand as a surrogate of inorganic matter and peat as a surrogate of organic matter. This range is very wide and covers all IC values of known carbon-rich soils on Earth. The experimental results show that self-heating ignition in different soil types is possible, even with the 86% inorganic content, but the tendency to ignite decreases quickly with increasing IC. We report a clear increase in ambient temperature required for ignition as the IC increases. Combining results from 39 thermostatically-controlled oven experiments, totalling 401h of heating time, with the Frank-Kamenetskii theory of ignition, the lumped chemical kinetic and thermal parameters are determined. We then use these parameters to upscale the laboratory experiments to soil layers of different thicknesses for a range of ambient temperatures ranging from 0°C to 40°C. The analysis predicts the critical soil layer thicknesses in nature for self-ignition at various possible environmental temperatures. For example, at 40°C a soil layer of 3% inorganic content can be ignited through self-heating if it is thicker than 8.8m, but at 86% IC the layer has to be 1.8km thick, which is impossible to find in nature. We estimate that the critical IC for a ambient temperature of 40°C and soil thickness of 50m is 68%. Because those are extreme values of temperature and thickness, no self-heating ignition of soil can be expected above the 68% threshold of inorganic content. This is the first in-depth experimental quantification of soil self-heating and shows that indeed it is possible that wildfires are initiated by self-heating in some soil types and conditions.
Highlights
Carbon-rich soils are porous reactive natural fuels found in nature, like histosols and gelisols [1]
The results found for the 3% IC experiments were used to estimate the ignition temperatures needed for higher ICs, reducing the number of experiments required for finding the critical ignition temperature at those given inorganic contents
Using the Frank-Kamenetskii theory, it is found that the effective activation energy for the soil increases from 105 kJ/ mol to 133 kJ/mol as IC increases from 3% to 86%, indicating a significant reduction in reactivity and ignitability
Summary
Carbon-rich soils are porous reactive natural fuels found in nature, like histosols and gelisols [1]. Examples of carbon-rich soil systems are natural peatlands [2]. As an organic porous media, carbon-rich soil is prone to smouldering ignition and combustion [5,10]. Smouldering wildland fires in soil systems, ranging from low to high inorganic contents, are a known natural hazard. Carbonrich soils burn the ancient carbon for months often causing the largest fires on Earth [3]. The effect of wildfires in carbon-rich soils like peatlands can be dramatic, as seen in Fig. 1 where a smouldering soil fire burnt for weeks in Las Tablas de Daimiel National park, Spain, in 2009. Global warming can dry the soils and increase soil combustion, creating a positive feedback to the climate system [2,4]
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