Influence of lignin and cellulose from termite-processed biomass on biochar production and evaluation of chromium VI adsorption

Sci Rep. 2024 Jun 28;14(1):14937. doi: 10.1038/s41598-024-65959-5.

Abstract

The increasing water contamination by toxic heavy metals, particularly hexavalent chromium, has become a significant environmental concern. This study explores the pyrolysis of termite-processed biomass, specifically Pinus elliottii particleboard and its termite droppings (TDs), to produce biochar and its application for chromium (VI) adsorption. Termite droppings, rich in lignin, and particleboard, rich in cellulose, were pyrolyzed at various temperatures to assess the effect of biomass composition on biochar properties. The study found that lignin-rich termite droppings produced biochar with higher fixed carbon content and specific surface area than cellulose-rich particleboard biochar. FTIR and Raman spectroscopy revealed significant molecular structure changes during pyrolysis, which influenced the adsorption capabilities of the biochar. Adsorption experiments demonstrated that TD biochar exhibited significantly higher chromium (VI) adsorption capacity, attributed to its distinct chemical composition and enhanced surface properties due to higher lignin content. These findings underscore the crucial role of lignin in producing efficient biochar for heavy metal adsorption, highlighting the practical applicability of termite-processed biomass in water purification technologies.

Keywords: Pinus elliottii; Adsorption; Chromium VI; Pyrolysis; Termite.

MeSH terms

  • Adsorption
  • Animals
  • Biomass*
  • Cellulose* / chemistry
  • Charcoal* / chemistry
  • Chromium* / chemistry
  • Isoptera* / chemistry
  • Lignin* / chemistry
  • Pinus / chemistry
  • Pyrolysis
  • Spectroscopy, Fourier Transform Infrared
  • Water Pollutants, Chemical / chemistry
  • Water Purification / methods

Substances

  • Charcoal
  • Lignin
  • Chromium
  • biochar
  • Cellulose
  • chromium hexavalent ion
  • Water Pollutants, Chemical