Physical–chemical characterization and thermal behavior of cassava harvest waste for application in thermochemical processes

Bioenergy generation from agroindustrial wastes has been investigated worldwide because of rising fossil fuel prices and the requirements of environmental legislation to reduce greenhouse gas emissions. In this research, the thermal behavior of cassava harvest wastes (husks, stalks, leaves) was inve...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry 2021-03, Vol.143 (5), p.3611-3622
Main Authors: Cruz, Glauber, Rodrigues, Alyson da Luz Pereira, da Silva, Darlan Ferreira, Gomes, Wolia Costa
Format: Article
Language:English
Subjects:
Air pollution
Air quality management
Aluminum
Analytical Chemistry
Biomass energy
Calcium
Calorimetry
Carbon
Cassava
Cellulose
Chemistry
Chemistry and Materials Science
Combustion
Crystal structure
Crystallinity
Diffraction
Energy bands
Energy minerals
Environmental law
Environmental legislation
Fossil fuels
Greenhouse gases
Hydrogen bonds
Inductively coupled plasma
Infrared analysis
Infrared spectroscopy
Inorganic Chemistry
Inorganic materials
Iron
Lignin
Lignocellulose
Measurement Science and Instrumentation
Optical emission spectroscopy
Oxidation
Physical Chemistry
Polymer Sciences
Pyrolysis
Scanning electron microscopy
Thermal analysis
Thermal degradation
Thermodynamic properties
X-rays
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Summary:Bioenergy generation from agroindustrial wastes has been investigated worldwide because of rising fossil fuel prices and the requirements of environmental legislation to reduce greenhouse gas emissions. In this research, the thermal behavior of cassava harvest wastes (husks, stalks, leaves) was investigated under two atmospheres: combustion (oxidizing) and pyrolysis (inert) by thermal analysis (TG/DTG curves). Other analytical techniques, such as X-ray diffraction, proximate and ultimate analyses, calorimetric analysis (HHV/LHV), scanning electron microscopy (SEM), Fourier transform infrared (FTIR), energy-dispersive spectroscopy (EDS), and inductively coupled plasma optical emission spectrometry (ICP-OES), were also applied to characterize them. The TG/DTG curves identified the main thermal degradation stages of the lignocellulosic materials, which correspond to average contents of hemicellulose (49.1%), cellulose (31.7%), lignin (16.2%), moisture (10.0%), ash (6.3%), volatile materials (68.0%), and fixed carbon (16.0%). X-rays showed a crystallinity index for the biomasses between 53.0 and 60.0%, confirming crystalline and amorphous regions. Metal composition determination by ICP-OES identified the main metallic and inorganic materials (K, Ca, Al, and Fe) present in the samples. SEM images revealed some morphological and structural differences, for example pores, roughness, fibers, and lamellae. FTIR was used mainly to evaluate the presence of energy bands or oxygen, carbon, and hydrogen bonds, confirming the data obtained by the ultimate analysis. EDS identified the behavior of the main organic and inorganic elements. All the results presented demonstrate the importance of this research and its application to science.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-020-09330-6