Effect of carbonization temperature on the microplasticity of wood-derived biocarbon

The uniaxial compression strength under stepped loading and the 325-nm-stepped deformation rate of biocarbon samples obtained by carbonization of beech wood at different temperatures in the 600–1600°C range have been measured using high-precision interferometry. It has been shown that the strength d...

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Published inPhysics of the solid state Vol. 56; no. 3; pp. 538 - 545
Main Authors Shpeizman, V. V., Orlova, T. S., Kardashev, B. K., Smirnov, B. I., Gutierrez-Pardo, A., Ramirez-Rico, J.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.03.2014
Springer
Subjects
Mechanical Properties
Physics
Physics and Astronomy
Physics of Strength
Plasticity
Solid State Physics
Carb
Medium Density Fiberboard
Deformation Rate
Carbonization Temperature
Deformation Curve
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Summary:The uniaxial compression strength under stepped loading and the 325-nm-stepped deformation rate of biocarbon samples obtained by carbonization of beech wood at different temperatures in the 600–1600°C range have been measured using high-precision interferometry. It has been shown that the strength depends on the content of nanocrystalline phase in biocarbon. The magnitude of deformation jumps at micro- and nanometer levels and their variation with a change in the structure of the material and loading time have been determined. For micro- and nanometer-scale jumps, standard deviations of the differences between the experimentally measured deformation rate at loading steps and its magnitude at the smoothed fitting curve have been calculated, and the correlation of the error with the deformation prior to destruction has been shown. The results obtained have been compared with the previously published data on measurements of the elastic properties and internal friction of these materials.
ISSN:1063-7834
1090-6460
DOI:10.1134/S1063783414030305