Matheus Poletto scite author profile

In this work, the relationship between cellulose crystallinity, the influence of extractive content on lignocellulosic fiber degradation, the correlation between chemical composition and the physical properties of ten types of natural fibers were investigated by FTIR spectroscopy, X-ray diffraction and thermogravimetry techniques. The results showed that higher extractive contents associated with lower crystallinity and lower cellulose crystallite size can accelerate the degradation process and reduce the thermal stability of the lignocellulosic fibers studied. On the other hand, the thermal decomposition of natural fibers is shifted to higher temperatures with increasing the cellulose crystallinity and crystallite size. These results indicated that the cellulose crystallite size affects the thermal degradation temperature of natural fibers. This study showed that through the methods used, previous information about the structure and properties of lignocellulosic fibers can be obtained before use in composite formulations.

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Thermal decomposition of wood: Influence of wood components and cellulose crystallite size

Poletto

Zattera

Forte

et al. 2012

Bioresource Technology

409

210

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Structural differences between wood species: Evidence from chemical composition, FTIR spectroscopy, and thermogravimetric analysis

Poletto

Zattera

Santana

2012

J. Appl. Polym. Sci.

216

124

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In this study, the relationship between wood cellulose crystallinity, influence of extractives on wood degradation, correlation between chemical composition, and physical properties of four wood species were investigated by chemical analysis, Fourier transform infrared (FTIR) spectroscopy, and thermogravimetry. The chemical analysis showed that Dipteryx odorata and Mezilaurus itauba (ITA) contained a higher quantity of extractives and lower quantities of holocellulose and lignin than Eucalyptus grandis (EUG) and Pinus elliottii. FTIR spectroscopy indicated that higher extractives content in ITA might be associated with more intense bands at 2920, 2850, and 1510 cm À1 . The lower values for hydrogen bond energy and hydrogen bond intensity showed that EUG contained more absorbed water than the other species. Thermogravimetry confirm that lower extractive contents leads to a better wood thermal stability. This study showed that through the methods used previous information about structure and properties of wood can be obtained before use it in composite formulations. V C 2012Wiley Periodicals, Inc. J Appl Polym Sci 126: E336-E343, 2012

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Thermal decomposition of wood: Kinetics and degradation mechanisms

Poletto

Zattera

Santana

2012

Bioresource Technology

235

101

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Crystalline properties and decomposition kinetics of cellulose fibers in wood pulp obtained by two pulping processes

Poletto¹,

Pistor²,

Zeni

et al. 2011

Polymer Degradation and Stability

170

104

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Structural Characteristics and Thermal Properties of Native Cellulose

Poletto¹,

Pistor²,

Zattera³

2013

114

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Characterization of composites based on expanded polystyrene wastes and wood flour

Poletto¹,

Dettenborn²,

Zeni

et al. 2011

Waste Management

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Materials produced from plant biomass: Part I: evaluation of thermal stability and pyrolysis of wood

Poletto¹,

Dettenborn²,

Pistor³

et al. 2010

Mat. Res.

100

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This paper compares the thermal stability of the sawdust of different wood species, an important factor in producing reinforced polymers. The compositions of two wood species, Pinus taeda and Eucalyptus grandis, were determined to evaluate the influence of the main wood components on the thermal stability of this material. The two species were submitted to thermogravimetric analysis at different heating rates to calculate the activation energy (E a ) using the Flynn-Wall-Ozawa (FWO) and Kissinger methods. The results suggest that larger quantities of holocellulose and lignin associated with lower extractive contents give the wood greater thermal stability. The E a values calculated for the two species were in the range of 146-165 kJ.mol -1. Evaluation of the activation energy values offers a simplified means to better understand the thermal decomposition of the sawdust of different wood species used in developing composites.

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Matheus Poletto

Native Cellulose: Structure, Characterization and Thermal Properties

Thermal decomposition of wood: Influence of wood components and cellulose crystallite size

Structural differences between wood species: Evidence from chemical composition, FTIR spectroscopy, and thermogravimetric analysis

Thermal decomposition of wood: Kinetics and degradation mechanisms

Crystalline properties and decomposition kinetics of cellulose fibers in wood pulp obtained by two pulping processes

Structural Characteristics and Thermal Properties of Native Cellulose

Characterization of composites based on expanded polystyrene wastes and wood flour

Materials produced from plant biomass: Part I: evaluation of thermal stability and pyrolysis of wood

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