Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar
Biochar is being increasingly applied for carbon dioxide (CO2) capture to preserve environmental quality. The use of soybean waste, soybean curd residue (SCR) as CO2 adsorbents can help to reduce the uncontrolled disposal of SCR. In this research, SCR-based biochar (Biochar@SCR) was prepared by pyro...
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my.um.eprints.436162023-10-26T03:36:39Z http://eprints.um.edu.my/43616/ Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar Zakaria, Dina Sofiea Mahmad Rozi, Siti Khalijah Abdul Halim, Hairul Nazirah Mohamad, Sharifah Mat Hussin, Siti Amira QD Chemistry Biochar is being increasingly applied for carbon dioxide (CO2) capture to preserve environmental quality. The use of soybean waste, soybean curd residue (SCR) as CO2 adsorbents can help to reduce the uncontrolled disposal of SCR. In this research, SCR-based biochar (Biochar@SCR) was prepared by pyrolysis process. For chemical activation, Biochar@SCR was immersed for 12 hours in 42.5 wt. H3PO4 solution at 1:1 ratio (g precursor/g H3PO4) to obtain Biochar@SCR-M1. Biochar@SCR-M2 was produced when Biochar@SCR-M1 was pyrolyzed again at 5000C for 2 hours. Elemental and functional groups analyses showed the presence of elemental phosphorus (P) and functional groups of P=O or P=OOH for Biochar@SCR-M1 and Biochar@SCR-M2, suggesting the chemical modification using H3PO4 was successful. Morphological analysis revealed the formation of pores after the pyrolysis process and chemical treatment with H3PO4. Analysis of CO2 adsorption depicted that the adsorption capacities of SCR, Biochar@SCR, Biochar@SCR-M1, and Biochar@SCR-M2 were 3.00 mg/g, 25.21 mg/g, 30.50 mg/g, and 36.00 mg/g, respectively. This result proved the increased CO2 sorption for H3PO4-treated Biochar@SCR, suggesting that phosphoric acid modification is an effective method for preparing biochar with high carbon dioxide adsorption. © 2022 Malaysian Institute of Chemistry. All rights reserved. 2022 Article PeerReviewed Zakaria, Dina Sofiea and Mahmad Rozi, Siti Khalijah and Abdul Halim, Hairul Nazirah and Mohamad, Sharifah and Mat Hussin, Siti Amira (2022) Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar. Malaysian Journal of Chemistry, 24 (2). 207 – 214. ISSN 15112292, |
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QD Chemistry Zakaria, Dina Sofiea Mahmad Rozi, Siti Khalijah Abdul Halim, Hairul Nazirah Mohamad, Sharifah Mat Hussin, Siti Amira Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
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Biochar is being increasingly applied for carbon dioxide (CO2) capture to preserve environmental quality. The use of soybean waste, soybean curd residue (SCR) as CO2 adsorbents can help to reduce the uncontrolled disposal of SCR. In this research, SCR-based biochar (Biochar@SCR) was prepared by pyrolysis process. For chemical activation, Biochar@SCR was immersed for 12 hours in 42.5 wt. H3PO4 solution at 1:1 ratio (g precursor/g H3PO4) to obtain Biochar@SCR-M1. Biochar@SCR-M2 was produced when Biochar@SCR-M1 was pyrolyzed again at 5000C for 2 hours. Elemental and functional groups analyses showed the presence of elemental phosphorus (P) and functional groups of P=O or P=OOH for Biochar@SCR-M1 and Biochar@SCR-M2, suggesting the chemical modification using H3PO4 was successful. Morphological analysis revealed the formation of pores after the pyrolysis process and chemical treatment with H3PO4. Analysis of CO2 adsorption depicted that the adsorption capacities of SCR, Biochar@SCR, Biochar@SCR-M1, and Biochar@SCR-M2 were 3.00 mg/g, 25.21 mg/g, 30.50 mg/g, and 36.00 mg/g, respectively. This result proved the increased CO2 sorption for H3PO4-treated Biochar@SCR, suggesting that phosphoric acid modification is an effective method for preparing biochar with high carbon dioxide adsorption. © 2022 Malaysian Institute of Chemistry. All rights reserved. |
| format |
Article |
| author |
Zakaria, Dina Sofiea Mahmad Rozi, Siti Khalijah Abdul Halim, Hairul Nazirah Mohamad, Sharifah Mat Hussin, Siti Amira |
| author_facet |
Zakaria, Dina Sofiea Mahmad Rozi, Siti Khalijah Abdul Halim, Hairul Nazirah Mohamad, Sharifah Mat Hussin, Siti Amira |
| author_sort |
Zakaria, Dina Sofiea |
| title |
Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| title_short |
Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| title_full |
Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| title_fullStr |
Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| title_full_unstemmed |
Enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| title_sort |
enhanced adsorption of carbon dioxide by phosphoric acid-modified soybean curd residue biochar |
| publishDate |
2022 |
| url |
http://eprints.um.edu.my/43616/ |
| _version_ |
1781704684112707584 |
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13.160551 |