Abstract
Research Highlights: Biochar is the carbonaceous product of pyrolysis or the gasification of biomass that is used as soil amendment to improve soil fertility and increase soil carbon stock. Biochar has been shown to increase, decrease, or have no effect on the emissions of greenhouse gases (GHG) from soil, depending on the specific soil and biochar characteristics. However, the temperature sensitivity of these gas emissions in biochar-amended soils is still poorly investigated. Background and Objectives: A pot experiment was set up to investigate the impact of woodchips biochar on the temperature sensitivity of the main GHG (CO2, CH4, and N2O) emissions from soil. Materials and Methods: Nine pots (14 L volume) were filled with soil mixed with biochar at two application rates (0.021 kg of biochar/kg of soil and 0.042 kg of biochar/kg of soil) or with soil alone as the control (three pots per treatment). Pots were incubated in a growth chamber and the emissions of CO2, CH4, and N2O were monitored for two weeks with a cavity ring-down gas analyzer connected to three closed dynamic chambers. The temperature in the chamber increased from 10 °C to 30 °C during the first week and decreased back to 10 °C during the second week, with a daily change of 5 °C. Soil water content was kept at 20% (w/w). Results: Biochar application did not significantly affect the temperature sensitivity of CO2 and N2O emissions. However, the sensitivity of CH4 uptake from soil significantly decreased by the application of biochar, reducing the CH4 soil consumption compared to the un-amended soil, especially at high soil temperatures. Basal CO2 respiration at 10 °C was significantly higher in the highest biochar application rate compared to the control soil. Conclusions: These results confirmed that the magnitude and direction of the influence of biochar on temperature sensitivity of GHG emissions depend on the specific GHG considered. The biochar tested in this study did not affect soil N2O emission and only marginally affected CO2 emission in a wide range of soil temperatures. However, it showed a negative impact on soil CH4 uptake, particularly at a high temperature, having important implications in a future warmer climate scenario and at higher application rates.
Highlights
Forest management can contribute to climate change mitigation by allocating woody biomass to bioenergy production, displacing fossil fuel use [1]
Our study showed that the reduction of soil CH4 uptake induced by biochar increased with soil temperature
The results of the present work show that biochar addition to soil did not significantly affect the sensitivity of CO2 and nitrous oxide (N2 O) fluxes, while it slightly increased the CO2 basal soil respiration in case of a high application rate, indicating that biochar application would not affect the emission of these gases in warmer climatic conditions
Summary
Forest management can contribute to climate change mitigation by allocating woody biomass to bioenergy production, displacing fossil fuel use [1]. Biochar has been shown to improve soil characteristics and plant productivity in agricultural and forest ecosystems [9,10,11,12,13] as well as reduce nutrient losses from soil [14,15,16]. For these reasons, biochar has been proposed in forest restoration as a replacement to other forms of organic amendments and liming agents, in degraded sites [9]. Applying biochar to forest soils may contribute to mitigate climate change through the increase of soil C stock, improve soil characteristics, and allow at the same time the valorization of the woody biomass gasification chain, by turning what is considered a waste into a resource
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