The role of soil microbial in the remediation of electronic waste

المؤلفون

  • Zainab Abood Sadoon
  • Saffa Aziz Mouhsen

DOI:

https://doi.org/10.32792/jeps.v13i2.296

الملخص

Undoubtedly, electronic goods made life easier for people and supplied It made life easier for everyone
and gave comfort. However ongoing updates, the short lifespan of electronic products, affordable prices,
and illegal disposal of electronic waste, as a result, electronic waste has made electronic waste faster
growing. This review highlights current bioremediation techniques, bacterial and fungal bioleaching
utilize normally occurring microorganisms and their by-products to extract valuable metals, which,
because of its affordability, environmental friendliness, and sustainability, is a promising technique.
Bacterial species are resistant to high concentrations of heavy metals and organic pollutants were
highlighted which have possibly potential remediation properties.

المراجع

[ 1] Bharathi, S. D., Dilshani, A., Rishivanthi, S., Khaitan, P., Vamsidhar, A., & Jacob, S. (2022).

Resource Recycling, Recovery, and Xenobiotic Remediation from E-wastes Through Biofilm

Technology: A Review. Applied Biochemistry and Biotechnology, 1-24.

[ 2] Chakraborty, S. C., Qamruzzaman, M., Zaman, M. W. U., Alam, M. M., Hossain, M. D.,

Pramanik, B. K., ... & Moni, M. A. (2022). Metals in e-waste: Occurrence, fate, impacts and

remediation technologies. Process Safety and Environmental Protection, 162, 230-252.

[ 3] Sadoon, Z. A., & Enayah, S. H. (2021). Serum Heavy Metals Level and OS among e-ic Waste

Exposed. Indian Journal of Forensic Medicine & Toxicology, 15(2), 3582-3587.

[ 4] Dawood, S. S. (2019). Future risk assessments of E-waste in Kurdistan Region of Iraq. Academic

Journal of Nawroz University, 8(4), 121-135.

[ 5] Arif, N., & Afroz, R. (2014). Electrical and electronic waste management–A case study in

University of Duhok, Iraq. Journal of Economics and Sustainable Development, 5(1), 21-27.

[ 6] Alziady, A. A. D. J. (2018). Studying the effect of institutional pressures on managers intentions

of Small enterprise in Thi-Qar province to adopt environmental disposal of electronic

waste. Managerial Studies Journal, 10(21).

[ 7] Hilal, R. H. (2019). (Polyacrylamide-Kaolin) Composite Used For Extraction Precious Metals

(Au+ 1, Ag+ 1) From Electronic Waste Solution by Using Hydrometallurgical Method. Wasit

Journal of Engineering Sciences, 7(3), 41-49.

[ 8] Hilal, R. H. (2020). Removal of Precious Metals from Electronic-Waste by Using Composite

Material. In IOP Conference Series: Materials Science and Engineering (Vol. 881, No. 1, p.

. IOP Publishing.

[ 9] Al-obaidy, O. F. H., Mawlood, S. J., & Al-Dulaimi, M. I. (2021). Evaluation of reverse

logistics options for international and local companies in Iraq. Indian Journal of Economics and

Business, 20(3).

[ 10] Hama, A. R., Tahir, T. A., & Ali, B. J. (2021). A study on solid waste generation, composition

and management in Sulaimania city, Kurdistan region, Iraq. In IOP Conference Series: Earth and

Environmental Science (Vol. 779, No. 1, p. 012049). IOP Publishing.

[ 11] Wu, Z., Gao, G., & Wang, Y. (2019). Effects of soil properties, heavy metals, and PBDEs on

microbial community of e-waste contaminated soil. Ecotoxicology and Environmental Safety,

, 705-714.

[ 12] Wu, Y., Song, Q., Wu, J., Zhou, J., Zhou, L., & Wu, W. (2021). Field study on the soil

bacterial associations to combined contamination with heavy metals and organic contaminants.

Science of The Total Environment, 778, 146282.

[ 13] Pradeepa, R., & Kavitha, K. K. (2020). Isolation and identification of heavy metal resistant

bacteria from an e-waste contaminated soil sites. Intl J Anal Exp Modal Anal, 12, 2259-2265.

[ 14] Wu, Y., Song, Q., Wu, J., Zhou, J., Zhou, L., & Wu, W. (2021). Field study on the soil

bacterial associations to combined contamination with heavy metals and organic

contaminants. Science of the Total Environment, 778, 146282.

[ 15] Wu, Z., Gao, G., & Wang, Y. (2019). Effects of soil properties, heavy metals, and PBDEs on

microbial community of e-waste contaminated soil. Ecotoxicology and Environmental

Safety, 180, 705-714.

[ 16] Narayanasamy, M., Dhanasekaran, D., & Thajuddin, N. (2021). Bioremediation of noxious

metals from e-waste printed circuit boards by Frankia. Microbiological Research, 245, 126707.

[ 17]Salam, M., Varma, A., & Chaudhary, D. (2020). Novel Arsenic resistant bacterium

Sporosarcina luteola M10 having potential bioremediation properties. J Microbiol Exp, 8(6), 213-

[ 18] Li, W., Fishman, A., & Achal, V. (2021). Ureolytic bacteria from electronic waste area, their

biological robustness against potentially toxic elements and underlying mechanisms. Journal of

Environmental Management, 289, 112517.

[ 19] Li, W., Fishman, A., & Achal, V. (2021). Ureolytic bacteria from electronic waste area, their

biological robustness against potentially toxic elements and underlying mechanisms. Journal of

Environmental Management, 289, 112517.

[ 20] Kaur, P., Sharma, S., Albarakaty, F. M., Kalia, A., Hassan, M. M., & Abd-Elsalam, K. A.

(2022). Biosorption and Bioleaching of Heavy Metals from Electronic Waste Varied with

Microbial Genera. Sustainability, 14(2), 935.

[ 21] Sikander, A., Kelly, S., Kuchta, K., Sievers, A., Willner, T., & Hursthouse, A. S. (2022).

Chemical and microbial leaching of valuable metals from PCBs and tantalum capacitors of spent

mobile phones. International journal of environmental research and public health, 19(16), 10006.

[ 22] Chang, T. T., Lin, Z. W., Zhang, L. Q., Liu, W. B., Zhou, Y., & Ye, B. C. (2022). Efficient

Biodegradation of Di-(2-Ethylhexyl) Phthalate by a Novel Strain Nocardia Asteroides LMB-7

Isolated From Electronic Waste Soil.

[ 23] Razali, M. S., Riyadi, F. A., Akhir, F. N. M., Yuzir, M. A. M., & Hara, H. (2021). Isolation

and characterization of copper leaching microbes from sanitary landfills for copper bioleaching of

waste printed circuit boards.

[ 24] Rosa, E., Di Piazza, S., Cecchi, G., Mazzoccoli, M., Zerbini, M., Cardinale, A. M., & Zotti,

M. (2022). Applied Tests to Select the Most Suitable Fungal Strain for the Recovery of Critical

Raw Materials from Electronic Waste Powder. Recycling, 7(5), 72.

[ 25] Sun, G. L., Reynolds, E., & Belcher, A. M. (2020). Using yeast to sustainably remediate and

extract heavy metals from waste waters. Nature Sustainability, 3(4), 303-311.

[ 26] Abraham, J., Chatterjee, A., & Sharma, J. (2020). Isolation and Characterization of Bacillus

licheniformis Strain for Bioleaching of Heavy Metals. Journal of Applied Biotechnology Reports,

(3), 139-144.

[ 27] Olubode, T. P., Amusat, A. I., Olawale, B. R., & Adekola, F. F. (2022). Biosorption of heavy

metals using bacterial isolates from e-waste soil. African Journal of Microbiology Research,

(7), 268-272.

[ 28] Sandil, S. (2023). Recent trends in bioremediation of heavy metals. In Metagenomics to

Bioremediation (pp. 23-53). Academic Press.

[ 29] Pant, D., Giri, A., & Dhiman, V. (2018). Bioremediation techniques for E-waste management.

Waste bioremediation, 105-125.

[ 30] RP, K. K. (2020). Isolation and identification of heavy metal resistant bacteria from an e-waste

contaminated soil sites. IJAEMA, 12, 2259-65.

[ 31] Minimol, M., Shetty K, V., & Saidutta, M. B. (2020). Process engineering aspects in

bioleaching of metals from electronic waste. Bioprocess Engineering for Bioremediation:

Valorization and Management Techniques, 27-44.

[ 32] Sharada, H. M., Abdel-Halim, S. A., Hafez, M. A., Elbarbary, T. A., Abdel-Fatah, Y., &

Ibrahim, I. A. (2021). Bioleaching of Copper from Electronic Waste Using Aspergillus niger.

[ 33] Mondal, S., & Palit, D. (2019). Effective role of microorganism in waste management and

environmental sustainability.sustainability. Sustainable agriculture, forest and environmental management, 485-

التنزيلات

منشور

2023-07-13