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Manuscript ID : JEST-1807-4366 (R2) Visit : 138 Page: 51 - 63

10.22034/jest.2021.37443.4366

Article Type: Original Research

Different Biochars Production and Their Effect on Removal of Cd (II), Ni (II) and Pb(II) from Irrigation water

Subject Areas : Environmental pollutions (water, soil and air)

Kiomars Sayyadian 1 , Abdolamir moezi 2 , Ali Gholami 3 , Ebrahim Panahpour 4 , Kamran Mohsen far 5

1 - Department of Soil Science, Khuzestan Science and Research Branch, Islamic Azad University, Ahvaz, Iran; Department of Soil Science, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran
2 - Associate Professor, Department of Soil Science, Chamran University of Ahwaz, Iran
3 - Associate Professor, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran. *(Corresponding author)
4 - Associate Professor, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
5 - Assistant Professor, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran

Received: 2018-07-04 Accepted : 2019-04-10 Published : 2020-12-21

Keywords: Cadmium, Nickel and Lea, Biochar,

Abstract :

Background and Objective: Today, hazard of surface and underground water contamination with heavy metals has led to a global concern. Therefore, the current study was carried out to assess the effects of different types and rates of biochar on irrigation water heavy metals content. Method: For this purpose, 12 different biochars were produced using 6 different biomasses including wheat stubble, pea stubble, maize residual, reed stem and leaves, olive meal and beet pulp at 500 and 700 C under low oxygen condition. According to specific area results, cation exchange capacity and infrared spectrophotometry, wheat stubble, reed stem and leaves and residual maize biochars, which produced at 700 °C were selected for further studies. Then effect of nine levels of these biochars on irrigation water heavy metals (cadmium, nickel and lead) content were investigated using a completely randomized design(CRD) with three replicates.  Findings: The results indicated that increase in temperature significantly reduce biochars yield, volatile compound percentage but increase acidity, cation exchange capacity, specific area and ash percentage. In addition, the results revealed that biochars and their applied doses could significantly reduce heavy metals content in irrigation water. Discussion and Conclusion: Increase in specific area, cation exchange capacity and acidity led to heavy metals elimination from irrigation water. Application of MB700 (compared with WB700 and RB700) and WB700 (compared with MB700 and RB700) could significantly reduce cadmium and nickel, respectively, whereas the effect of MB700 and WB700 in eliminating of lead was more pronounced than RB700. The maximum cadmium, lead and Nickel reduction was related to apply 32 g per liter biochar.  

References:


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  27. Thavamani, S.S., Rajkumar, R., 2013. Removal of heavy metal Cr(II),Pb(II) and Ni(II) from aqueous solution by adsorption on alumina. Res. J.Chem Sci., 3(8), pp 44-48.
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  28. Okoya A.A., Akinyele, A.B., Ofoezie, I.E., Amuda, O.S., Alayande, O.S. and Makinde, O.W. 2014. Adsorption of heavy metal ions chitosoan grafted cocoa husk char. Aferican Journal of Pure and applied Chemistry, Vol. 8(10), PP 147-161.
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  1. Adil, S., Mashiatullah, A., Asma, M., Abid, J. and Ghaffar, A., 2014. Heavy metal removal efficiency of paper mulberry biochar and commercially available silica powder from simulated industerial wastewater. Iranica Journal of Energy & Environment, 5(4): 446-452.
    2.
  2. Emenike, P.C., Omole, D.O., Ngene, B.U. and Tenebe, I.T., 2016. Potencially of agricultural adsorbent for sequestering of metal ionsfrom wastewater. Global J. Inviron.Sci.Manage., 2(4):411- 442.
    3.
  3. Barakat, M.A., 2011. New trends in removing heavy metals from industrial wasetwater. Arabian Journal of chemistry, 4, 361-377.
    4.
  4. Inyang, M., Gao, B., Y. Yao, Y., Xue, Y., A.N.Zimmerman, A.N., Pullammanappallil,P. and Cao, X., 2012. Removal of heavy metals from aqueous solution by biochar derived from anaerobically digested biomass. Bioresour, Technology.
    5.
  5. [5]Alkhashman, O., 2009. Chemical evaluation of Ma a sewage effluents and its reuse in irrigation purposes, Water Resour. Manag, 23, pp 1041-1053.
    6.
  6. Fu, F. and Wang, Q., 2011. Removal heavy metal ions from wastewater: a review. Journal of Environmental management, 92(3), 407-418.
    7.
  7. Rao, R. A. K. and Ikram, S., 2011. Sorption studies of Cu on gooseberry fruit (Emblica officinalis) and its removal from electroplanting wastewater, Desalination, 277(1):390-398.
    8.
  8. Komkiene, J., Baltrenaite, E., 2016. Biochar as adsorbent for removal heavy metal ions [ Cadmium (II), Copper (II), Lead (II), Zink (II)] from aqueous phase. Int. J. Environ. Sci. Technol., 13, pp 471-482.
    9.
  9. Leung, W. C.,Wang, M. F. , Chaua, H., Lo, W., Leung, C. K., 2000. Removal and recovery of heavy metals by bacteria isolated from activated sludge treating industrial effluents and muncipal wastewater, Water Sci. Technol. 41(12), pp 233-240.
    10.
  10. Elzobair, K., 2013. Biochar effects on soil microbial communities and resistance of enzymes to stress (thesis), Department of Soil and Crop Science, Colorado State University.
    11.
  11. Chavda S.B., Pandya, M.J., 2014. Evaluation of removal TDS, COD and heavy metals from wastewater using biochar. IJIRT Volume 1 Issue 9.

    1. Gavili, A.,S. A. A. Mosavi, A. A. Kamkar Haghighi. 2016. Effect of Cattle manure and drought stress on growth characteristic  and water use efficiency of spinach under grrenhouse  condition. Journal of  Water Research in agriculture.30.2(2):243-259 
      2.
    2. Li, H., Dong,X., Evandro, B., Silva,D., Letuzia, M., Oliveira,D., Chen,Y.and Q. Lena. 2017.Mechanisms of metal sorption by biochars: Biochar characteristics and Modifications. Elsevier..Chemosphere 178 (2017) 466e478
      3.

  12. Sadaka, S.,Sharara, M.A., Ashworth, A., Keyser, P., Allen, F., Wright, A., 2014 .Characterization of biochar from switchgrass carbonizatin. Energies 7, pp548-567. doi: 10.3390/en7020548
    13.
  13. ASTM International. D5142, Standard Test Method for Proximate Analysis of the analysis Sample of Coal and Koke Instrumental Procedures In American Society for Testing and Material; ASTM International , USA, 2009.
    14.
  14. Song, W. and Guo, M., 2012. Quality variations of poultry litter biochar generated at different pyrolysis temperature. J. Anal. Appl. Pyrolysis 94, pp 138-145.
    15.
  15. Wolf, B., 1982. The comprehensive system of lead analysis and its use for diagnosing crop nutrient status. Comm Soil Sci. Plant Anal. 13, pp 1035-1059.
    16.
  16. Zhang, J., Lu, F., Zhang, H., Shao, L., Chen, D. and P. He, P., 2015. Multiscale visualization of the structural and characteristic changes of sewage sludge biochar oriented towards potential agronomic and environmental implication, Scientific Report. www.nature.com/Scientific report
    17.
  17. Cantrell, K. B., Hunt, P. G., Uchimiya, M., Novak, J. M., and Ro, K. S., 2012. Impact of pyrolysis temperature and manure sources on physiochemical characteristic of biochar, Bioresource Technol., 107, pp 419-428.
    18.
  18. Novak, J., Lima, I., Xing, B., Gaskin, J. W., Steiner, C., Das, K. C., Ahmenda, M., Rehrah, D., Watts, D. W., Busscher, W. J., and Harry, S., 2009. Characterization of designer biochar producted at different temperatures and their effects on loamy sand, Annals Environ Sci., 3, pp 195-206.
    19.
  19. da Silva, I. C., Basilo, J.J.N., Fernandes, L.C., Colen, F., Sampaio, R.A., Frazáo, L.A., 2017. Biochip from different residues on soil properties and commen bean production, Sci: Agric. V74, n.5, pp 378-382.
    20.
  20. Zhao, S.X., Ta, N.T., Wang, X.D., 2017. Effect of temperature on structural and physicochemical properties of biochip with apple tree branches as feedstock material. Energies, 10, 1293. www.mdpi.com/Journal/energies
    21.
  21. Joseph,S. D., Arbestain, M.C., Lin, Y., Munroe, P., Chia, C.H., Hook, J., L. V. Zwieten, L.V., Kimber, S., Cowie, A., Singh, B.P., Lehmann, L., Foidl, N., Smernik, R.J. and Amonette, J.E., 2010. An investigation into the reactions of biochar in soil, Australian Journal of Soil Research, 48, pp 501- 5015.
    22.
  22. Tan X., Liu, T., Zeng, G., Wang, X., Hu, X. and Gu, Y., 2015. Application of biochar fo removal of pollutants aqueous solution, Chemosphere, 125, pp 70-85.
    23.
  23. Ahmad, M., A. U. Rajapaksha, J. E. Lim, M. Zheng, M. Bolan, D. Mohan, M. Vithanage, S. S. Lee.2014. Biochar as a sorbent for contaminant management in soil and water. Chemosphere 99, 19-33
    24.
  24. Rasheed, A., S. Sana, S.R. Kashif, Z. Umer and M. Khatoon.2017. To evaluate the efficiency of char and biochar for waste water treatment. Journal of waste recycling vol. 2 No2:7
    25.
  25. Xu, R. K., S. C. Xiao, J. H. Yuan, A. Z. Zhao. 2011. Adsorbtion methyle violet from aqueous solutions by the biochar derived from residues. Bioresour. Technol. 102, 10293-10298
    26.
  26. Kumar, R. S., 2012. Global environmental changes and its adverse on human health: A sociological concern. J. Ecosyst. Ecogr., 01(S1).
    27.
  27. Thavamani, S.S., Rajkumar, R., 2013. Removal of heavy metal Cr(II),Pb(II) and Ni(II) from aqueous solution by adsorption on alumina. Res. J.Chem Sci., 3(8), pp 44-48.
    28.
  28. Okoya A.A., Akinyele, A.B., Ofoezie, I.E., Amuda, O.S., Alayande, O.S. and Makinde, O.W. 2014. Adsorption of heavy metal ions chitosoan grafted cocoa husk char. Aferican Journal of Pure and applied Chemistry, Vol. 8(10), PP 147-161.
    29.
  29. Moezzi, A.,Khademalrasoul, A., Biria, M.,2017. "Biochar and its application", first ed. Shahid Chamran University, Ahvaz, pp.257.
    30.

 

 

 

 

 

 

 
 

 
 

 
 

 

 

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