Your search keyword '"Saeed, Anwar"' showing total 2 results

1. Elucidating the Effects of Reaction Time on the Physicochemical Characterization of Valorized Synthesized Alumina.

Author

Bin Mokaizh, Aiman A., Shariffuddin, Jun Haslinda, Baarimah, Abdullah O., Al-Fakih, Amin, Mohamed, Abdullah, Baarimah, Salem O., Al-Mekhlafi, Al-Baraa Abdulrahman, Alenezi, Hamoud, Olalere, Olusegun Abayomi, and Saeed, Anwar Ameen Hezam

Subjects

ALUMINUM oxide, SOL-gel processes, POROSITY, METROPOLITAN areas, CRYSTAL structure, CORUNDUM

Abstract

Aluminum waste-can management in Malaysia has recently become a serious environmental and public health issue, particularly in metropolitan areas. This has prompted the need to valorize these waste-cans into value-added products using the most economical and environmentally friendly techniques. In this study, the sol–gel technique was used to synthesize high-quality alumina from the aluminum waste-cans collected. From this method, the observed peaks of the synthesized alumina were identified as diaspore (α-AlO(OH)), boehmite (γ-AlO(OH)), aluminum oxide, or gamma-alumina (γ-Al2O3) crystalline structure and corundum. The morphological configuration, microstructure, and functional group properties of the synthesized alumina were evaluated. All the synthesized alumina exhibited a non-spherical shape and appeared to have hexagonal-like shape particles. Moreover, the XRD patterns of the synthesized alumina AL-6-30 and AL-12-30 exhibited a small angle (1–10°) with no XRD peak, which indicated a mesoporous pore structure with no long-range order. The overall results of γ-alumina synthesized from the aluminum waste-cans showed an optimal condition in producing a highly structured γ-alumina with excellent surface-area characteristics. The synthesized alumina exhibited stronger and highly crystalline functional characteristics almost comparable with the commercially available brands on the market. [ABSTRACT FROM AUTHOR]

Published

2022

2. Heavy Metals Capture from Water Sludge by Kenaf Fibre Activated Carbon in Batch Adsorption.

Author

Saeed, Anwar Ameen Hezam, Harun, Noorfidza Yub, and Zulfani, Neisha

Subjects

HEAVY metals, KENAF, HEAVY elements, SEWAGE sludge, SEWAGE disposal plants, ACTIVATED carbon

Abstract

The Malaysia's wastewater treatment plant has yet to find an environmentally alternative for the sludge treatment before disposal. In majority of cases, the sludge containing a high amount of heavy metals including Fe, Ti, Mn, Zn, As, Cu, Ni, Zr, and Ga, is disposed to the environment through landfill. The recovery of valuable materials such as manganese from the sludge is an alternative path towards zero dumpings of schedule waste as well as a way of reducing the possible pollutant release to the environment. It can be achieved through adsorption, as it provides a cheap yet flexible, method which is simple and easy to implement. Kenaf derived from Hibiscus cannabis was proven as a good adsorbent material for the heavy metals recovery. This project aims at utilizing Kenaf fiber as activated carbon to recover heavy metals from wastewater sludge in batch adsorption. The adsorbent surface area and pore characteristics and elemental analysis were observed under adsorbent characterization. The effect of contact time, sludge pH and temperature to the removal efficiency was investigated. The adsorption isotherm was also studied. The result showed that the developed kenaf activated carbon is a promising adsorbent which might be used for some heavy metals. From batch adsorption study, it was observed that KFAC is able to remove an average 30% of the heavy metal element from the sludge. It was also found that the best removal is achieved in a neutral pH solution, increasing the contact time will increase the equilibrium uptake, while the increasing temperature will increase the percent removal of heavy metals. It was concluded that the Kenaf based activated carbon can be used for the recovery of heavy metals from the wastewater sludge through batch adsorption. [ABSTRACT FROM AUTHOR]

Published

2020