4.7 Article

Pyrolysis of sesame residue: Evolution of the volatiles and structures of biochar versus temperature

Journal

ENVIRONMENTAL TECHNOLOGY & INNOVATION
Volume 24, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.eti.2021.101859

Keywords

Pyrolysis; Solid waste; Pyrolysis temperature; Residence time; Distribution of the products; Properties of biochar

Funding

  1. National Natural Science Foundation of China [51876080]
  2. Program for Taishan Scholars of Shandong Province Government
  3. Agricultural Innovation Program of Shandong Province [SD2019NJ015]
  4. R & D program of Shandong Basan Graphite New Material Plant

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The study found that cracking reactions dominate the distribution of products of sesame residue at high temperatures and heating rates, with nitrogen-containing organics being cracked into gases above 350 degrees C. The organic components in sesame residue are not thermally stable, leading to low carbon yield, low heating value, and low energy yield in the production of biochar.
Sesame residue is a solid waste produced in the process of production of sesame oil, which can be used as feedstock for the production of biofuels and carbon materials via thermochemical process. This study explores the pyrolysis behavior of sesame residue at different pyrolysis temperatures and heating rates, aiming to explore the effects of temperature and heating rates on the distribution and properties of sesame residue products. Sesame residue contains more aliphatic alkanes and N-containing organics than biomass, and thus cracking reactions dominated distribution of products, at especially increased pyrolysis temperature with high heating rates. Majority of the nitrogen-containing organics were cracked into condensable organics at 350 degrees C and into gases above this temperature. The abundant long-chain aliphatics also made the bio-oil different from that from biomass pyrolysis. The organic components in sesame residual were generally not thermally stable, a significant portion of which was converted into volatile organics or gases, producing the biochar with low carbon yield, low heating value and the low energy yield. Additionally, the change of functionalities of the biochar versus temperature was investigated, providing reference information for tailoring structure of biochar for further use as functional carbon materials. (C) 2021 Elsevier B.V. All rights reserved.

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