Waste remediation: Low-temperature synthesis of hybrid Cu(OH)2/CuO and CuO nanostructures from spent printed circuit boards and their dye degradation studies

Gautam, P and De, A K and Rao, M D and Sinha, I and Behera, C K and Singh, K K (2023) Waste remediation: Low-temperature synthesis of hybrid Cu(OH)2/CuO and CuO nanostructures from spent printed circuit boards and their dye degradation studies. Environmental Science and Pollution Research .

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Abstract

The demand for environmentally friendly and sustainable resource utilization techniques for recycling waste printed circuit boards is significant due to their status as valuable secondary resources, containing high-purity copper and precious metals. In this context, Cu(OH)(2)/CuO and CuO nanostructures were fabricated using alkaline precipitation and low-temperature aging methods using the strip solution originated from a laboratory-scale spent mobile phone printed circuit board recovery process. XRD, FTIR, FESEM-EDX, and TEM were utilized to characterize the as-recovered nanoproducts. A hybrid structure of Cu(OH)(2)/CuO was formed at 70 & DEG, C, and a monoclinic CuO phase was formed at 80 & DEG; C aging time. The results show that Cu(OH)(2)/CuO nanoflakes have an average crystallite size of 24.06 nm and a particle width of 22 & plusmn; 3 nm. Cu(OH)(2)/CuO nanoflakes formed at 70 & DEG; C aging temperature and 24-h residence time have finer crystallite and particle sizes than CuO-ridged nanospheres formed at 80 & DEG; C aging temperature. The optical band gap energy of Cu(OH)(2)/CuO and CuO nanostructures formed was found to be 2.28 eV and 2.22 eV, respectively. The hybrid Cu(OH)(2)/CuO nanostructure photocatalyzed the decomposed 97.28% rhodamine blue using a visible light source, whereas the CuO nanostructure degraded only 14.64% rhodamine blue dye under similar conditions. A surfactant-less hybrid structure is developed without the use of any chemical precursor. Thus, a high-value-added product is produced using one waste material to remove another waste in wastewater treatment.

Item Type:Article
Official URL/DOI:https://10.1007/s11356-023-29005-7
Uncontrolled Keywords:Cu(OH)(2), CuO, Nanostructures, Nanoflakes, Printed circuit boards, Rhodamine blue, Photocatalytic Degradation, Copper, Nanoparticles, Adsorption, Microwave
Divisions:Material Science and Technology
ID Code:9460
Deposited By:HOD KRIT
Deposited On:21 Dec 2023 12:54
Last Modified:21 Dec 2023 12:54
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