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Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina

Year 2020, Volume: 10 Issue: 1, 73 - 83, 01.03.2020
https://doi.org/10.21597/jist.599528

Abstract

Effect of microalgal pyrolytic bio-char on the copper ions removal from water was investigated. Scanning Electron Microscope (SEM) and elemental analysis were done for bio-char before the adsorption experiments. Adsorbent dosage (10-40 g L-1), copper concentration (10 000-20 000 mg L-1), time (15-90 min) parameters were changed. UV visible spectrometer was used to analyze the results. The most adjustible kinetic and adsorption model with data were specified as Pseudo-Second-Order and Freundlich respectively. Maximum adsorption capacity and removal efficiency were found as nearly 150 mg Cu(II) g-1 bio-char and 20% respectively.To characterize the char after the adsorption, it was took the advantage of fouirer transform infrared spectrophotometer (FTIR).

References

  • Bordoloi N, Goswami R, Kumar M, Kataki R, 2017. Biosorption of Co (II) from Aqueous Solution Using Algal Biochar: Kinetics and Isotherm Studies. Bioresource technology, 244: 1465-1469.
  • Chiaramonti D, Prussi M, Buffi M, Rizzo M, Pari L, 2017. Review and Experimental Study on Pyrolysis and Hydrothermal Liquefaction of Microalgae for Biofuel Production. Applied Energy, 185: 963-972.
  • Goh L, Sethupathi S, Bashir J, Ahmed W, 2019. Adsorptive Behaviour of Palm Oil Mill Sludge Biochar Pyrolyzed at Low Temperature for Copper and Cadmium Removal. Journal of environmental management, 237: 281-288.
  • Hass A, Lima M, 2018. Effect of Feed Source and Pyrolysis Conditions on Properties and Metal Sorption by Sugarcane Biochar. Environmental Technology and Innovation, 10: 16-26.
  • Hodgson E, Lewys-James A, Ravella R, Thomas-Jones S, Perkins W, Gallagher J, 2016. Optimisation of Slow-Pyrolysis Process Conditions to Maximise Char Yield and Heavy Metal Adsorption of Biochar Produced from Different Feedstocks. Bioresource technology, 214: 574-581.
  • Hoslett J, Ghazal H, Ahmad D, Jouhara H, 2019. Removal of Copper Ions from Aqueous Solution Using Low Temperature Biochar Derived from the Pyrolysis of Municipal Solid Waste. Science of the Total Environment, 673: 777-789.
  • Inyang I, Gao B, Yao Y, Xue Y, Zimmerman A, Mosa A, Cao X, 2016. A Review of Biochar as a Low-Cost Adsorbent for Aqueous Heavy Metal Removal. Critical Reviews in Environmental Science and Technology, 46(4): 406-433.
  • Komkiene J, Baltrenaite E, 2016. Biochar as Adsorbent for Removal of Heavy Metal Ions [Cadmium (II), Copper (II), Lead (II), Zinc (II)] from Aqueous Phase. International Journal of Environmental Science and Technology, 13(2): 471-482.
  • Leng J, Yuan Z, Huang J, Wang H, Wu B, Fu H, Zeng M, 2015. Characterization and Application of Bio-Chars from Liquefaction of Microalgae, Lignocellulosic Biomass and Sewage Sludge. Fuel Processing Technology, 129: 8-14.
  • Park H, Cho J, Ryu C, Park K, 2016a. Removal of copper (II) in aqueous solution using pyrolytic biochars derived from red macroalga Porphyra tenera. Journal of Industrial and Engineering Chemistry, 36 : 314-319.
  • Park H, Ok S, Kim H, Cho S, Heo S, Delaune D, Seo C, 2016b. Competitive adsorption of heavy metals onto sesame straw biochar in aqueous solutions. Chemosphere, 142: 77-83.
  • Qian L, Zhang W, Yan J, Han L, Gao W, Liu R, Chen M, 2016. Effective removal of heavy metal by biochar colloids under different pyrolysis temperatures. Bioresource Technology, 206 : 217-224.
  • Salema A, Ting W, Shang K, 2019. Pyrolysis of blend (oil palm biomass and sawdust) biomass using TG-MS. Bioresource Technology, 274: 439-446.
  • Semelsberger A, Borup L, Greene L, 2006. Dimethyl ether (DME) as an alternative fuel. Journal of Power Sources, 156(2) : 497-511.
  • Suliman W, Harsh B, Abu-Lail I, Fortuna M, Dallmeyer I, Garcia-Perez M, 2016. Influence of feedstock source and pyrolysis temperature on biochar bulk and surface properties. Biomass and Bioenergy, 84: 37-48.
  • Wang B, Bai Z, Jiang H, Prinsen P, Luque R, Zhao S, Xuan J, 2019. Selective heavy metal removal and water purification by microfluidically-generated chitosan microspheres: Characteristics, modeling and application. Journal of Hazardous Materials, 364 : 192-205.
  • Xiao Y, Xue Y, Gao F, Mosa A, 2017. Sorption of heavy metal ions onto crayfish shell biochar: effect of pyrolysis temperature, pH and ionic strength. Journal of the Taiwan Institute of Chemical Engineers, 80: 114-121.
  • Xie Q, Addy M, Liu S, Zhang B, Cheng Y, Wan Y, Ruan R, 2015. Fast microwave-assisted catalytic co-pyrolysis of microalgae and scum for bio-oil production. Fuel, 160 : 577-582.
  • Zhang L, Zeng Y, Cheng Z, 2016. Removal of heavy metal ions using chitosan and modified chitosan: A review. Journal of Molecular Liquids, 214 : 175-191.

Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina

Year 2020, Volume: 10 Issue: 1, 73 - 83, 01.03.2020
https://doi.org/10.21597/jist.599528

Abstract

Effect of microalgal pyrolytic bio-char on the copper ions removal from water was investigated. Scanning Electron Microscope (SEM) and elemental analysis were done for bio-char before the adsorption experiments. Adsorbent dosage (10-40 g L-1), copper concentration (10 000-20 000 mg L-1), time (15-90 min) parameters were changed. UV visible spectrometer was used to analyze the results. The most adjustible kinetic and adsorption model with data were specified as Pseudo-Second-Order and Freundlich respectively. Maximum adsorption capacity and removal efficiency were found as nearly 150 mg Cu(II) g-1 bio-char and 20% respectively.To characterize the char after the adsorption, it was took the advantage of fouirer transform infrared spectrophotometer (FTIR).

References

  • Bordoloi N, Goswami R, Kumar M, Kataki R, 2017. Biosorption of Co (II) from Aqueous Solution Using Algal Biochar: Kinetics and Isotherm Studies. Bioresource technology, 244: 1465-1469.
  • Chiaramonti D, Prussi M, Buffi M, Rizzo M, Pari L, 2017. Review and Experimental Study on Pyrolysis and Hydrothermal Liquefaction of Microalgae for Biofuel Production. Applied Energy, 185: 963-972.
  • Goh L, Sethupathi S, Bashir J, Ahmed W, 2019. Adsorptive Behaviour of Palm Oil Mill Sludge Biochar Pyrolyzed at Low Temperature for Copper and Cadmium Removal. Journal of environmental management, 237: 281-288.
  • Hass A, Lima M, 2018. Effect of Feed Source and Pyrolysis Conditions on Properties and Metal Sorption by Sugarcane Biochar. Environmental Technology and Innovation, 10: 16-26.
  • Hodgson E, Lewys-James A, Ravella R, Thomas-Jones S, Perkins W, Gallagher J, 2016. Optimisation of Slow-Pyrolysis Process Conditions to Maximise Char Yield and Heavy Metal Adsorption of Biochar Produced from Different Feedstocks. Bioresource technology, 214: 574-581.
  • Hoslett J, Ghazal H, Ahmad D, Jouhara H, 2019. Removal of Copper Ions from Aqueous Solution Using Low Temperature Biochar Derived from the Pyrolysis of Municipal Solid Waste. Science of the Total Environment, 673: 777-789.
  • Inyang I, Gao B, Yao Y, Xue Y, Zimmerman A, Mosa A, Cao X, 2016. A Review of Biochar as a Low-Cost Adsorbent for Aqueous Heavy Metal Removal. Critical Reviews in Environmental Science and Technology, 46(4): 406-433.
  • Komkiene J, Baltrenaite E, 2016. Biochar as Adsorbent for Removal of Heavy Metal Ions [Cadmium (II), Copper (II), Lead (II), Zinc (II)] from Aqueous Phase. International Journal of Environmental Science and Technology, 13(2): 471-482.
  • Leng J, Yuan Z, Huang J, Wang H, Wu B, Fu H, Zeng M, 2015. Characterization and Application of Bio-Chars from Liquefaction of Microalgae, Lignocellulosic Biomass and Sewage Sludge. Fuel Processing Technology, 129: 8-14.
  • Park H, Cho J, Ryu C, Park K, 2016a. Removal of copper (II) in aqueous solution using pyrolytic biochars derived from red macroalga Porphyra tenera. Journal of Industrial and Engineering Chemistry, 36 : 314-319.
  • Park H, Ok S, Kim H, Cho S, Heo S, Delaune D, Seo C, 2016b. Competitive adsorption of heavy metals onto sesame straw biochar in aqueous solutions. Chemosphere, 142: 77-83.
  • Qian L, Zhang W, Yan J, Han L, Gao W, Liu R, Chen M, 2016. Effective removal of heavy metal by biochar colloids under different pyrolysis temperatures. Bioresource Technology, 206 : 217-224.
  • Salema A, Ting W, Shang K, 2019. Pyrolysis of blend (oil palm biomass and sawdust) biomass using TG-MS. Bioresource Technology, 274: 439-446.
  • Semelsberger A, Borup L, Greene L, 2006. Dimethyl ether (DME) as an alternative fuel. Journal of Power Sources, 156(2) : 497-511.
  • Suliman W, Harsh B, Abu-Lail I, Fortuna M, Dallmeyer I, Garcia-Perez M, 2016. Influence of feedstock source and pyrolysis temperature on biochar bulk and surface properties. Biomass and Bioenergy, 84: 37-48.
  • Wang B, Bai Z, Jiang H, Prinsen P, Luque R, Zhao S, Xuan J, 2019. Selective heavy metal removal and water purification by microfluidically-generated chitosan microspheres: Characteristics, modeling and application. Journal of Hazardous Materials, 364 : 192-205.
  • Xiao Y, Xue Y, Gao F, Mosa A, 2017. Sorption of heavy metal ions onto crayfish shell biochar: effect of pyrolysis temperature, pH and ionic strength. Journal of the Taiwan Institute of Chemical Engineers, 80: 114-121.
  • Xie Q, Addy M, Liu S, Zhang B, Cheng Y, Wan Y, Ruan R, 2015. Fast microwave-assisted catalytic co-pyrolysis of microalgae and scum for bio-oil production. Fuel, 160 : 577-582.
  • Zhang L, Zeng Y, Cheng Z, 2016. Removal of heavy metal ions using chitosan and modified chitosan: A review. Journal of Molecular Liquids, 214 : 175-191.
There are 19 citations in total.

Details

Primary Language English
Subjects Environmental Engineering
Journal Section Çevre Mühendisliği / Environment Engineering
Authors

Gamze Özçakır 0000-0003-0357-4176

Publication Date March 1, 2020
Submission Date July 31, 2019
Acceptance Date November 7, 2019
Published in Issue Year 2020 Volume: 10 Issue: 1

Cite

APA Özçakır, G. (2020). Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina. Journal of the Institute of Science and Technology, 10(1), 73-83. https://doi.org/10.21597/jist.599528
AMA Özçakır G. Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina. J. Inst. Sci. and Tech. March 2020;10(1):73-83. doi:10.21597/jist.599528
Chicago Özçakır, Gamze. “Adsorption of Cu(II) from Aqueous Solution by Using Pyrolytic Bio-Char of Spirulina”. Journal of the Institute of Science and Technology 10, no. 1 (March 2020): 73-83. https://doi.org/10.21597/jist.599528.
EndNote Özçakır G (March 1, 2020) Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina. Journal of the Institute of Science and Technology 10 1 73–83.
IEEE G. Özçakır, “Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina”, J. Inst. Sci. and Tech., vol. 10, no. 1, pp. 73–83, 2020, doi: 10.21597/jist.599528.
ISNAD Özçakır, Gamze. “Adsorption of Cu(II) from Aqueous Solution by Using Pyrolytic Bio-Char of Spirulina”. Journal of the Institute of Science and Technology 10/1 (March 2020), 73-83. https://doi.org/10.21597/jist.599528.
JAMA Özçakır G. Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina. J. Inst. Sci. and Tech. 2020;10:73–83.
MLA Özçakır, Gamze. “Adsorption of Cu(II) from Aqueous Solution by Using Pyrolytic Bio-Char of Spirulina”. Journal of the Institute of Science and Technology, vol. 10, no. 1, 2020, pp. 73-83, doi:10.21597/jist.599528.
Vancouver Özçakır G. Adsorption of Cu(II) from aqueous solution by using pyrolytic bio-char of Spirulina. J. Inst. Sci. and Tech. 2020;10(1):73-8.