Please use this identifier to cite or link to this item: http://hdl.handle.net/123456789/856
Title: Preliminary Study of the Potential Graphene Oxide as Radioactive Clinical Wastewater Adsorbability in Nuclear Medicine
Authors: Abdul Razab M.K.A. 
Manso M.S. 
Noor A.M. 
Rozi S.M. 
Abd Latif N.F.F. 
Nizam Jaafar K. 
Jamaludin F. 
Keywords: Agglomeration;Graphene;Nuclear medicine;Oxygen;Physicochemical properties;Radioactive wastes;Radioactivity;Radioisotopes;Sediments;Water filtration
Issue Date: 28-Dec-2020
Publisher: IOP Publishing Ltd
Conference: International Conference on Science and Technology 2020, ICoST 2020 
Abstract: 
This paper reports the ability of graphene oxide (GO) as a radionuclide adsorbent material for an alternative approach in nuclear medicine radioactive waste management. Notable physicochemical properties of GO mainly consist of oxygen-containing functional groups on its basal plane and edges site in the form of epoxy, hydroxyl, and carboxyl groups, making it a promising candidate for radionuclide extraction material from aqueous solution. Herein, GO was synthesised via a simplified Hummers method. The radioactive clinical waste, which is urine, was collected right after the scanning procedure and mixed with GO in various concentrations: 1 mg/ml, 1.5 mg/ml, 2 mg/ml, 2.5 mg/ml, and 3 mg/ml. The mixture was then filtered using micropore filter paper, leaving sediments on the filter paper and wastewater residues. The radioactivity of sediment and water residue was determined by using a well counter after 3, 6, 9, and 12 hours of filtration process. The activities of the sediment and water residues were found to be decreased with increasing GO concentrations. The FESEM image revealed high agglomeration structure when the sample was treated with GO of 3 mg/ml concentration. Further analysis via EDX showed the presence of other elements in the urine, which led to its attraction to the GO-layered sheets. This analysis also confirmed the presence of oxygen-functioning group in GO that facilitated the agglomeration process and solidified the radionuclide waste.
Description: 
Scopus
URI: http://hdl.handle.net/123456789/856
ISSN: 17551307
DOI: 10.1088/1755-1315/596/1/012037
Appears in Collections:Faculty of Bioengineering and Technology - Proceedings

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