Recycling of some solid wastes to produce silica anchored on graphene oxide as sorbent material for uranium ions

Prof. Mohamed Farid Cheira

Abstract: 

Uranium ions may expand into the setting through enforcement, industry, and mining, posing risks to mortal health and biological situations due to radiation and toxicity. Nevertheless, by the widespread use of atomistic energy and further applications, U(VI) is exceptionally loosed into the running solutions; it threatens environmental safety and biological balance. So, U(VI) elimination and deposition from liquid origins are fateful to nucleate energy engendering and peripheral protection. To earn U(VI) outputting from radioactive trash water financially workable, the extracting materials must maintain the features of huge extracting ability, selectivity, departure rate, and reusability. Up to promptly, the utmost study directs on the implementation of extracting materials for U(VI) departure owing to the performance facility, low-price, capability, and broad versatility.

          The wet process captured silica from rice husk, and also graphene oxide was made from carbon stocks of Zn-C batteries waste via the Hummer processes. The organized silica was attached to the gained graphene oxide to acquire silica/graphene oxide (SiO₂/GO) as a sorbent. SiO₂/GO was discriminated upon EDX, BET, XRD, SEM, and FTIR. Practical attitudes toward U(VI) sorption include pH, sorption time, SiO₂/GO dose, U(VI) concentration, and temperature were premeditated.  The practical consequences disclosed that the superlative U(VI) uptake on SiO₂/GO is 145.0 mg/g with pH4. The kinetic statistics fit fine through the pseudo-2nd order modeling. Also, Langmuir's sorption modeling designated well the sorption isotherm; nevertheless, sorption progression was random, spontaneous, besides exothermic. Additionally, SiO₂/GO was essentially regenerated with a S:L ratio of 1:50 of 0.8 M H₂SO₄ and a 60 min eluting time. Sorption-desorption seven cycles were executed to inspect the practicality and frequent usage of SiO₂/GO.