African Journal of
Pure and Applied Chemistry

  • Abbreviation: Afr. J. Pure Appl. Chem.
  • Language: English
  • ISSN: 1996-0840
  • DOI: 10.5897/AJPAC
  • Start Year: 2007
  • Published Articles: 357

Full Length Research Paper

Metakaolin clay-derived geopolymer for recycling of waste cathode ray tube glass

Mary B. Ogundiran
  • Mary B. Ogundiran
  • Analytical/Environmental Chemistry Unit, Department of Chemistry, University of Ibadan, Oyo State, Nigeria.
  • Google Scholar
Ikpeni S. Enakerakpo
  • Ikpeni S. Enakerakpo
  • Analytical/Environmental Chemistry Unit, Department of Chemistry, University of Ibadan, Oyo State, Nigeria.
  • Google Scholar


  •  Received: 25 April 2018
  •  Accepted: 13 June 2018
  •  Published: 30 June 2018

References

Duxson P, Provis JL, Lukey GC, Mallicoat SW, Kriven WM, Van Deventer JSJ (2005). Understanding the relationship between geopolymer composition, microstructure and mechanical properties. Colloids and Surfaces: Colloids and Surfaces A: Physicochemical and Engineering Aspects 269:47-58.
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Iniaghe PO, Adie GU, Osibanjo O (2013). Assessment of toxic heavy metals levels in obsolete computer monitor components discarded within vicinities of electronic workshops. Toxicological and Environmental Chemistry 95:1108-1115.
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Jang YC, Townsend TG (2003). Leaching of Lead from Computer Printed Wire Boards and Cathode Ray Tubes by Municipal Solid Waste Landfill Leachates. Environmental Science and Technology 37:4778-4784.
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Kim D, Petrisor IG, Yen TF (2005). Evaluation of biopolymer-modified concrete systems for disposal of cathode ray tube glass. Journal of the Air and Waste Management Association 55(7):961-969.
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Kumar A, Kumar S (2013). Development of paving blocks from synergistic use of red mud and fly ash using geopolymerisation. Construction and Building Materials 38:865-871.
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Lairaksa N, Moon AR, Makul N (2013). Utilisation of cathode ray tube waste: encapsulation of PbO-containing funnel glass in Portland cement clinker. Journal of Environmental Management 117:180-186.
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Ling TC, Poon CS (2011). Utilisation of recycled glass derived from cathode ray tube glass as fine aggregate in cement mortar. Journal of Hazardous Materials 192(2):451-456.
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Ling TC, Poon CS (2012). A comparative study on the feasible use of recycled beverage and CRT funnel glass as fine aggregate in cement mortar. Journal of Cleaner Production 29-30:46-52.
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Ogundiran MB, Ikotun OJ (2014). Investigating the Suitability of Nigerian calcined kaolins as raw materials for geopolymer binders. Transactions of the Indian Ceramic Society 73(2):138-142.
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Ogundiran MB, Kumar S (2015). Synthesis and characterisation of geopolymer from Nigerian Clay. Applied Clay Science 108:173-181.
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Ogundiran MB, Nugteren HW, Witkamp GJ (2013). Immobilisation of lead smelting slag within spent aluminate-fly ash based geopolymers. Journal of Hazardous Materials 248-249:29-36.
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Ogundiran MB, Sanjay K (2016). Synthesis of fly ash-calcined clay geopolymers: Reactivity, mechanical strength, structural and microstructural characteristics. Construction and Building Materials 125:450-457.
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Ogundiran MB, Winjobi FA (2015). The potential of binary blended geopolymer binder containing Ijero-Ekiti calcined kaolin clay and ground waste window glass. African Journal of Pure and Applied Chemistry 9(7):159-166.
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Pacheco-Torgal F, Castro-Gomes J, Jalali S (2007). Investigations about the effect of aggregates on strength and microstructure of geopolymeric mine waste mud binders. Cement and Concrete Research 37:933-941.
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Saeed A, Zhang L (2012). Production of eco-friendly bricks from copper mine tailings through geopolymerisation. Construction and Building Materials 29:323-331.
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Shao Y, Lefort T, Moras S, Rodriguez D (2000). Studies on concrete containing ground waste glass. Cement and Concrete Research 30:91-100.
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Singh N, Li J, Zeng X (2017). Global responses for recycling waste CRTs in e-waste. Waste Management 57:187-197.
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Singh N, Li J, Zeng, X (2016). Solutions and challenges in recycling waste cathode-ray tubes. Journal of Cleaner Production 133:188-200.
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Sua-iam G, Makul N (2013). Use of limestone powder during incorporation of Pb-containing cathode ray tube waste in self-compacting concrete. Journal of Environmental Management 128:931-940.
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van Jaarsveld JGS, van Deventer JSJ (1996). The Potential Use of Geopolymeric Materials to Immobilise Toxic Metals. Part I: Theory and Applications. Minerals Engineering 10(7):659-669.
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