Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn
In this work, palm-shell waste powder activated carbon (PPAC) coated by magnesium silicate (PPAC-MS) were successfully synthesized by the impregnation of magnesium silicate (MgSiO3) using economical material (silicon dioxide powder) via mild hydrothermal approach under one-pot synthesis for the f...
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my.um.stud.97002021-01-26T22:21:31Z Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn Choong , Choe Earn TA Engineering (General). Civil engineering (General) In this work, palm-shell waste powder activated carbon (PPAC) coated by magnesium silicate (PPAC-MS) were successfully synthesized by the impregnation of magnesium silicate (MgSiO3) using economical material (silicon dioxide powder) via mild hydrothermal approach under one-pot synthesis for the first time. Surprisingly, PPACMS exhibited a homogeneous thin plate mesh-like structure, as well as meso- and macro-pores with a high surface area of 772.1 m2 g-1. Different impregnation ratios of MgSiO3 onto PPAC were tested from 0% to 300%. High amounts of MgSiO3 led to high Cu (II) adsorption capacity. A ratio of 1:1, designated as PPAC-MS 100, was considered optimum because of its chemical stability in solution. The maximum adsorption capacity of PPAC-MS 100 for Cu (II) obtained by isotherm experiments was 369 mg g-1. Kinetic adsorption data fitted to pseudo-second-order revealed chemisorption. Increasing ionic strength reduced Cu (II) adsorption capacity because of the competition effect between Na+ and Cu2+. Three times of regeneration studies were also conducted for Cu (II) removal. In addition, PPAC-MS 100 showed sufficient adsorption capacity on removal Zn (II), Al (III), Fe (II), Mn (II), and As (V) with the adsorption capacity of 373 mg g-1, 244 mg g-1, 234 mg g-1, 562 mg g-1, 191 mg g-1, respectively. As an effective adsorbent, PPAC-MS 100 simultaneously removes Bisphenol A (BPA) and Pb (II) in single and binary mode. Due to its specific morphological characteristics, PPAC-MS 100 had adsorption capacities of Pb (II) as high as 419.9 mg g-1 and 408.8 mg g-1 in single mode and binary mode based on Freudliuch isotherm model while those for BPA by PPAC-MS were 168.4 mg g-1 and 254.7 mg g-1 for single mode and binary modes corresponding to Langmuir isotherm model. Experiment results also indicated that the synergistic removal of BPA occurred because the precipitation process of Pb (II) leads to the co-precipitation of BPA with Pb(OH)2 compound. PPAC-MS showed a good reusability for 5 regeneration cycles using Mg (II) solution followed by thermal treatment. PPAC-MS is characterized by Fourier Transformed Infrareds (FTIR), nitrogen adsorption/desorption analysis, X-Ray powder diffraction (XRD), X-ray photoelectron spectroscopy (XPS) and Field Emission Scanning Electron Microscope (FESEM). Overall, PPAC-MS has a high potential in the treatment process for wastewater containing both toxic heavy metals and emerging pollutants due to its high sorption capacities and reusability, while remaining economical through the reuse of palm-shell waste materials. 2018-11 Thesis NonPeerReviewed application/pdf http://studentsrepo.um.edu.my/9700/1/Choong_Choe_Earn.pdf application/pdf http://studentsrepo.um.edu.my/9700/2/Choong_Choe_Earn_%2D_Thesis.pdf Choong , Choe Earn (2018) Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn. PhD thesis, University of Malaya. http://studentsrepo.um.edu.my/9700/ |
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TA Engineering (General). Civil engineering (General) Choong , Choe Earn Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| description |
In this work, palm-shell waste powder activated carbon (PPAC) coated by magnesium
silicate (PPAC-MS) were successfully synthesized by the impregnation of magnesium
silicate (MgSiO3) using economical material (silicon dioxide powder) via mild
hydrothermal approach under one-pot synthesis for the first time. Surprisingly, PPACMS
exhibited a homogeneous thin plate mesh-like structure, as well as meso- and
macro-pores with a high surface area of 772.1 m2 g-1. Different impregnation ratios of
MgSiO3 onto PPAC were tested from 0% to 300%. High amounts of MgSiO3 led to
high Cu (II) adsorption capacity. A ratio of 1:1, designated as PPAC-MS 100, was
considered optimum because of its chemical stability in solution. The maximum
adsorption capacity of PPAC-MS 100 for Cu (II) obtained by isotherm experiments was
369 mg g-1. Kinetic adsorption data fitted to pseudo-second-order revealed
chemisorption. Increasing ionic strength reduced Cu (II) adsorption capacity because of
the competition effect between Na+ and Cu2+. Three times of regeneration studies were
also conducted for Cu (II) removal. In addition, PPAC-MS 100 showed sufficient
adsorption capacity on removal Zn (II), Al (III), Fe (II), Mn (II), and As (V) with the
adsorption capacity of 373 mg g-1, 244 mg g-1, 234 mg g-1, 562 mg g-1, 191 mg g-1,
respectively. As an effective adsorbent, PPAC-MS 100 simultaneously removes
Bisphenol A (BPA) and Pb (II) in single and binary mode. Due to its specific
morphological characteristics, PPAC-MS 100 had adsorption capacities of Pb (II) as
high as 419.9 mg g-1 and 408.8 mg g-1 in single mode and binary mode based on
Freudliuch isotherm model while those for BPA by PPAC-MS were 168.4 mg g-1 and
254.7 mg g-1 for single mode and binary modes corresponding to Langmuir isotherm
model. Experiment results also indicated that the synergistic removal of BPA occurred
because the precipitation process of Pb (II) leads to the co-precipitation of BPA with Pb(OH)2 compound. PPAC-MS showed a good reusability for 5 regeneration cycles
using Mg (II) solution followed by thermal treatment. PPAC-MS is characterized by
Fourier Transformed Infrareds (FTIR), nitrogen adsorption/desorption analysis, X-Ray
powder diffraction (XRD), X-ray photoelectron spectroscopy (XPS) and Field Emission
Scanning Electron Microscope (FESEM). Overall, PPAC-MS has a high potential in the
treatment process for wastewater containing both toxic heavy metals and emerging
pollutants due to its high sorption capacities and reusability, while remaining
economical through the reuse of palm-shell waste materials. |
| format |
Thesis |
| author |
Choong , Choe Earn |
| author_facet |
Choong , Choe Earn |
| author_sort |
Choong , Choe Earn |
| title |
Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| title_short |
Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| title_full |
Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| title_fullStr |
Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| title_full_unstemmed |
Magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / Choong Choe Earn |
| title_sort |
magnesium silicate impregnation on palm-shell activated carbon powder for enhanced heavy metal adsorption / choong choe earn |
| publishDate |
2018 |
| url |
http://studentsrepo.um.edu.my/9700/1/Choong_Choe_Earn.pdf http://studentsrepo.um.edu.my/9700/2/Choong_Choe_Earn_%2D_Thesis.pdf http://studentsrepo.um.edu.my/9700/ |
| _version_ |
1738506291697942528 |
| score |
13.160551 |