Abundant and Stable Char Residues in Soils: Implications for Soil Fertility and Carbon Sequestration

Mao, Jingdong; Johnson, Robert L.; Lehmann, Johannes; Olk, Daniel C.; Neves, Eduardo G.; Thompson, Michael L.; Schmidt‐Rohr, Klaus

doi:10.1021/es301107c

Cited by 249 publications

(101 citation statements)

References 40 publications

(106 reference statements)

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“…In non-forest systems chars are increasingly recognized as playing a critical role in soil nutrient dynamics as well as constituting a long-term C stock (Spokas 2010). For example, recent results suggest that nearly all the cation exchange capacity of Mollisols, some of the world's most productive agricultural soils, may be attributable to pyrogenic carbon (Mao et al 2012). There is remarkably little information available on the distribution of natural chars, their properties, and their potential role in soil processes and forest productivity, particularly in forest ecosystems with relatively long natural fire return intervals.…”

Section: Biochar and Natural Disturbance Emulationmentioning

confidence: 99%

Biochar and forest restoration: a review and meta-analysis of tree growth responses

2015

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Biochar'', or charcoal intended for use as a soil amendment, has received great attention in recent years as a means of enhancing carbon sequestration and soil properties in agricultural systems. Here we address the potential for biochar use in the context of forest restoration, reviewing relevant experimental studies on biochar use in forest ecosystems, the properties of chars generated from wood waste material, and available data on tree growth responses to biochar. To our knowledge the earliest mention of char use as a soil amendment is actually specifically in the context of forest restoration (in the 1820s in Scotland). Wood waste biochars have an unusual set of properties that suggest their applicability in a forest restoration context: namely, high recalcitrance promoting long-lasting effects, retention of cations, anions, and water, in the soil, sorptive properties that can reduce bioavailability of a wide range of toxic materials, and relative ease of production from locally available feedstocks. A meta-analysis of recent studies on biochar responses of woody plants indicates a potential for large tree growth responses to biochar additions, with a mean 41 % increase in biomass. Responses are especially pronounced at early growth stages, and appear to be higher in boreal and tropical than in temperate systems, and in angiosperms than conifers; however, there is high variability, and field studies are few. The properties of biochars also vary greatly depending on feedstock and pyrolysis conditions; while this complicates their use, it provides a means to design biochars for specific restoration situations and objectives. We conclude that there is great promise for biochar to play an important role in a wide variety of forest restoration efforts, specifically as a replacement product for other forms of organic matter and liming agents.

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Section: Biochar and Natural Disturbance Emulationmentioning

confidence: 99%

Biochar and forest restoration: a review and meta-analysis of tree growth responses

2015

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“…Gasification biochar generally contains a considerable amount of minerals and recalcitrant carbon and is considered an attractive product for soil amendment due to its fertilizer and carbon sequestration potential [3,4]. Carbon sequestration in soil mitigates the effect of climate change [5], and may furthermore help to maintain or even improve the soil fertility. This is of key importance to be able to fulfill the increasing global demand for producing crops for both food and energy [6].…”

Section: Introductionmentioning

confidence: 99%

Gasification biochar as a valuable by-product for carbon sequestration and soil amendment

Hansen

Müller-Stöver

Ahrenfeldt

et al. 2015

Biomass and Bioenergy

165

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Soil quality improvement a b s t r a c tThermal gasification of various biomass residues is a promising technology for combining bioenergy production with soil fertility management through the application of the resulting biochar as soil amendment. In this study, we investigated gasification biochar (GB) materials originating from two major global biomass fuels: straw gasification biochar (SGB) and wood gasification biochar (WGB), produced by a Low Temperature Circulating Fluidized Bed gasifier (LT-CFB) and a TwoStage gasifier, respectively, optimized for energy conversion. Stability of carbon in GB against microbial degradation was assessed in a shortterm soil incubation study and compared to the traditional practice of direct incorporation of cereal straw. The GBs were chemically and physically characterized to evaluate their potential to improve soil quality parameters. After 110 days of incubation, about 3% of the added GB carbon was respired as CO 2 , compared to 80% of the straw carbon added. The stability of GB was also confirmed by low H/C and O/C atomic ratios with lowest values for WGB (H/C 0.12 and O/C 0.10). The soil application of GBs exhibited a liming effect increasing the soil pH from ca 8 to 9. Results from scanning electron microscopy and BET analyses showed high porosity and specific surface area of both GBs, indicating a high potential to increase important soil quality parameters such as soil structure, nutrient and water retention, especially for WGB. These results seem promising regarding the possibility to combine an efficient bioenergy production with various soil aspects such as carbon sequestration and soil quality improvements.

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“…where k is defined as the rate constant of reaction whose temperature dependence is expressed by the Arrhenius equation: (2) where Eα is the apparent activation energy (kJ mol ). The rate of transformation from solid-state to volatile product is described by the following expression: 11,12 (3) where α is the conversion degree of the process; k(T) is the time of process; f(α) is the rate constant and the reaction model.…”

Section: Kinetic Studymentioning

confidence: 99%

“…The organic oxygen in the samples is evolved during the pyrolysis according to the level of hemicelluloses and lignin breakdown. The main wave numbers considered on the FTIR peaks of the biochars for air and nitrogen atmospheres were: CO 2 By the analysis of the generated absorbance is observed how much energy was absorbed in a specific wavelength region. Overall is noted that the pyrolysis atmosphere is an important parameter, because peak intensities are greater under air atmosphere and demonstrate the more oxidized status of the sample, thus leading to more potential safety and storage risks.…”

Section: Ignition and Burnout Temperaturesmentioning

confidence: 99%

“…Biochar is a carbon rich solid material produced by thermal decomposition of organic matter, generally biomass wastes. 2 Biochar is also known as a multifunctional material in agro-systems which is employed primarily as a soil conditioner for immobilizing metals, improvement of drought resistance, recovery and fertilization of the soil. 3 Both biomass and biochar can be used to design and fulfill a lifecycle favoring a competitive agricultural based world economy, inside farms and overall agro and energy based industries.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Investigation on Prospective Energy Power from Corncob Husk Biomass and its Biochars by Kinetic Parameters and Isoconversional Models

Bueno

Maia

Morais

et al. 2017

J. Braz. Chem. Soc.

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The biofuel properties of biomass play an important role in achieving their utilization on agro-systems and industries. In this context the biomass waste of maize, corncob husk, and its biochars were taken into account to be investigated by thermogravimetric analysis, thermodynamic parameters for non-isothermal analyses using the Ozawa-Flynn-Wall kinetic isoconversional model in order to comprehend its possible fuels features. It was also investigated the compounds generated after pyrolysis and their relation with oxidation reactions for the safe-handling and storage. It was found that corncob husk biochar produced at 300 °C shows the best qualities as a solid biofuel, since it requires less energy input through pyrolysis to be produced. Finally, analysing the compounds generated and remained on the biochar's surface, by Fourier transform infrared spectroscopy (FTIR) analysis, biochars produced at low temperatures present one of the lowest features prone to oxidation reactions.

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Abundant and Stable Char Residues in Soils: Implications for Soil Fertility and Carbon Sequestration

Cited by 249 publications

References 40 publications

Biochar and forest restoration: a review and meta-analysis of tree growth responses

Biochar and forest restoration: a review and meta-analysis of tree growth responses

Gasification biochar as a valuable by-product for carbon sequestration and soil amendment

Investigation on Prospective Energy Power from Corncob Husk Biomass and its Biochars by Kinetic Parameters and Isoconversional Models

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