Overview of biochar for electrochemistry applications

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Nutrients’ fate in cow manure during hydrothermal treatments

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Production and characterization of biochar from industrial sludge for potential agronomic use

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Woody and agricultural biomass diversity in torrefaction: A complete study in solid conversion and volatiles formation on TGA-GCMS

Nowadays, there is an increasing awareness on the importance of biomass waste as a renewable source of energy, materials and chemicals. In this context, the European project MOBILE FLIP aims at developing and demonstrating mobile conversion processes suitable with various underexploited agro- and forest based biomass resources in order to produce energy carriers, materials and chemicals. One of these processes is torrefaction, which consists in a mild thermal treatment, occurring typically between 200 and 300°C during a few tens of minutes in a default-oxygen atmosphere. Please click on the file below for full content of the abstract

Fast Pyrolysis of Biomass Under Gasification Conditions: Influence of Particle Size, Reactor Temperature and Gas Phase Reactions

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Biochars from various biomass types as anodes for sodium-ion batteries

Until now, the applications targeted for biochars have mostly been focused in the field of energy, as combustion fuel, or of agronomy, as soil amendment. However, high-added value materials in the field of electrochemistry are now more and more mentioned as promising applications to investigate (Deng et al. 2016). At the moment, one major topic in electrochemistry is the development of alternative to lithium-ion battery in order to solve the issue of lithium supply. One of the most mature options is sodium-ion battery (Wang et al. 2016). In such battery, anode is generally made up of hard carbon, that has surface area below 10 m2.g-1 and subnanometric pores. Please click on the file below for full content of the abstract

Assessing the impact of woody and agricultural biomass variability on its behaviour in torrefaction through Principal Component Analysis

The influence of biomass macromolecular composition on its behaviour in torrefaction was statistically assessed through Principal Component Analysis (PCA), both in terms of solid conversion kinetics and volatile species released, in function of the operating conditions. The experimental data obtained in the torrefaction of 14 woody and agricultural biomass samples at lab-scale was analysed. Main biomass macromolecular composition on cellulose, hemicelluloses and lignin was shown to acceptably represent biomass diversity, which can be complemented by the extractives and ash content. Similitudes were found in deciduous and coniferous wood families, respectively, while agricultural and herbaceous crops were shown as more heterogeneous, both in terms of characterization and behaviour in torrefaction. Cellulose, hemicelluloses and lignin content strongly influenced solid and volatile species yields in torrefaction, while biomass family exhibited a lower impact. Ash content in potassium, phosphorous and silicon did not show any influence on the extent of solid degradation through torrefaction. A lower variability was found in solid degradation profiles from woods, while agricultural crop behaviour was more heterogeneous. Different volatile species were released from biomass samples from the same family. Furthermore, different production profiles were found for volatile species chemically close, except for deciduous wood. These results indicate that, when modelling biomass torrefaction, solid mass loss can be represented by an exemplar of deciduous and coniferous wood, while several species would be required for the agricultural family. The variability of the volatile species release would require the consideration of several volatile species and several biomass samples per famil