SYNTHESIS AND INVESTIGATION OF ELECTROCHEMICAL PROPERTIES OF REDUCED GRAPHENE OXIDE-BASED COMPOSITES

Qadeer Ahmed; Waqas Jahangir; Hina Tahir; Ansar Abbas; Shahid Ali; Muhammad Arif; Eraj Muzaffar; Jigar Allah Ditta

doi:10.71146/kjmr438

Authors

Qadeer Ahmed Department of Chemistry, Lahore Garrison University (LGU) Sector-C Avenue-4, Phase 6 DHA, Lahore, Pakistan. Author
Waqas Jahangir Department of Chemistry, Lahore Garrison University (LGU) Sector-C Avenue-4, Phase 6 DHA, Lahore, Pakistan. Author
Hina Tahir National Agricultural Research Centre, Islamabad, Pakistan. Author
Ansar Abbas Department of Basic and Applied Chemistry, Faculty of Science and Technology, University of Central Punjab, Khayaban-e-Jinnah Road, Johar Town, Lahore-54782, Pakistan. Author
Shahid Ali Department of Basic and Applied Chemistry, Faculty of Science and Technology, University of Central Punjab, Khayaban-e-Jinnah Road, Johar Town, Lahore-54782, Pakistan. Author
Muhammad Arif Department of Chemistry, Minhaj University Lahore, Township Lahore, Pakistan. Author
Eraj Muzaffar Department of Chemistry, Lahore Garrison University (LGU) Sector-C Avenue-4, Phase 6 DHA, Lahore, Pakistan. Author
Jigar Allah Ditta Department of Chemistry, Lahore Garrison University (LGU) Sector-C Avenue-4, Phase 6 DHA, Lahore, Pakistan. Author

DOI:

https://doi.org/10.71146/kjmr438

Keywords:

Composite, Electrochemical, Synthesis, Voltammograms, Diffusion

Abstract

Graphene oxide-based composites enhance electrochemical performance by improving conductivity, stability, and surface area, making them ideal for energy storage, sensors, and catalytic applications. In this study, Graphene oxide-based composites were synthesized to improve their performance in different electrochemical applications. RGO-based composites were synthesized using the hydrothermal method. XRD, FTIR, and SEM Electrochemical measurements (CV) were used to characterize the synthesized material. Electrochemical measurements (CV) were observed utilizing a three-electrode setup using composite-coated Ni foam. The nature of surface-active sites was detected from the voltammograms. Among the RGO-based composites studied, RGO- MoO2 demonstrated superior capacitive performance, achieving a maximum capacitance of 1851.60 F/g at a scan rate of 10 mV/s. This outperforms both RGO-CdO (1643.70 F/g) and RGO-CuO (1206.90 F/g). The enhanced capacitance of RGO- MoO2 is attributed to its larger surface area and more porous structure, which facilitate better electrolyte accessibility and ion diffusion within the material.

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Author Biography

Qadeer Ahmed, Department of Chemistry, Lahore Garrison University (LGU) Sector-C Avenue-4, Phase 6 DHA, Lahore, Pakistan.

Completed MBBS from Islamic International Medical College, Housejob done from Pakistan Railway Hospital, Main author of this article