Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production
Hydrogen or syngas, valued for its clean and high-energy properties, stands as a promising solution to future energy shortages by converting CO2 and CH4 waste into renewable syngas through a reaction known as methane bi-reforming. Hence, the purpose of this current research is to examine the effecti...
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| Format: | Article |
| Language: | English |
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Taylor & Francis
2024
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| Online Access: | https://umpir.ump.edu.my/id/eprint/45289/ |
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| author | Irna Haslina, Ibrahim Nor Shafiqah, Mohd Nasir Nuremirah Syafiqah, Suhaimi Li, Maoshua Cuong Nguyen, Van Sumaiya, Zainal Abidin |
| author_facet | Irna Haslina, Ibrahim Nor Shafiqah, Mohd Nasir Nuremirah Syafiqah, Suhaimi Li, Maoshua Cuong Nguyen, Van Sumaiya, Zainal Abidin |
| author_sort | Irna Haslina, Ibrahim |
| building | UMP Institutional Repository |
| collection | Online Access |
| description | Hydrogen or syngas, valued for its clean and high-energy properties, stands as a promising solution to future energy shortages by converting CO2 and CH4 waste into renewable syngas through a reaction known as methane bi-reforming. Hence, the purpose of this current research is to examine the effectiveness of Cu/MnO2 catalyst in methane bi-reforming (MBR) using response surface methodology (RSM). The synthesis of the 15%Cu/MnO2 catalyst was accomplished using the ultrasonic impregnation method, followed by a comprehensive analysis and characterization of the catalyst using CO2-TPD, BET, H2-TPR, TPO, and XRD evaluation. The effect of reaction parameters was investigated using RSM analysis, including temperature, CO2/CH4 ratio, and gas hourly space velocity (GHSV) (700–900 °C, 0.2–1.0, and 16–36 L g cat−1 h−1, respectively). According to the analysis of variance and three-dimensional response surface plots, it was determined that CH4 conversion and H2 yield were largely influenced by temperature, whereas CO2 conversion and CO yield could be manipulated through CO2/CH4 feed ratio. Meanwhile, the GHSV appeared to have a significant influence on the H2/CO ratio and CH4 conversion. From the experimental data, it was found that the 15%Cu/MnO2 catalyst performed best under specified optimal conditions of 800 °C, a CO2/CH4 ratio of 0.6, and a GHSV of 26 L g cat−1 h−1. These optimal conditions resulted in the maximum conversion of CH4 (54.67%), CO2 conversion (47.52%), H2 yield (43.81%), CO yield (36.29%), and H2/CO ratio (1.384). Despite the inevitability of carbon formation resulting from the breakdown of CH4 and CO at high temperatures, the examination of the spent catalysts under optimal conditions yielded a smaller quantity of carbon of approximately 28.27% in comparison to the suboptimal conditions with 55.37%. |
| first_indexed | 2025-11-15T03:59:43Z |
| format | Article |
| id | ump-45289 |
| institution | Universiti Malaysia Pahang |
| institution_category | Local University |
| language | English |
| last_indexed | 2025-11-15T03:59:43Z |
| publishDate | 2024 |
| publisher | Taylor & Francis |
| recordtype | eprints |
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| spelling | ump-452892025-08-07T03:15:07Z https://umpir.ump.edu.my/id/eprint/45289/ Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production Irna Haslina, Ibrahim Nor Shafiqah, Mohd Nasir Nuremirah Syafiqah, Suhaimi Li, Maoshua Cuong Nguyen, Van Sumaiya, Zainal Abidin QD Chemistry TP Chemical technology Hydrogen or syngas, valued for its clean and high-energy properties, stands as a promising solution to future energy shortages by converting CO2 and CH4 waste into renewable syngas through a reaction known as methane bi-reforming. Hence, the purpose of this current research is to examine the effectiveness of Cu/MnO2 catalyst in methane bi-reforming (MBR) using response surface methodology (RSM). The synthesis of the 15%Cu/MnO2 catalyst was accomplished using the ultrasonic impregnation method, followed by a comprehensive analysis and characterization of the catalyst using CO2-TPD, BET, H2-TPR, TPO, and XRD evaluation. The effect of reaction parameters was investigated using RSM analysis, including temperature, CO2/CH4 ratio, and gas hourly space velocity (GHSV) (700–900 °C, 0.2–1.0, and 16–36 L g cat−1 h−1, respectively). According to the analysis of variance and three-dimensional response surface plots, it was determined that CH4 conversion and H2 yield were largely influenced by temperature, whereas CO2 conversion and CO yield could be manipulated through CO2/CH4 feed ratio. Meanwhile, the GHSV appeared to have a significant influence on the H2/CO ratio and CH4 conversion. From the experimental data, it was found that the 15%Cu/MnO2 catalyst performed best under specified optimal conditions of 800 °C, a CO2/CH4 ratio of 0.6, and a GHSV of 26 L g cat−1 h−1. These optimal conditions resulted in the maximum conversion of CH4 (54.67%), CO2 conversion (47.52%), H2 yield (43.81%), CO yield (36.29%), and H2/CO ratio (1.384). Despite the inevitability of carbon formation resulting from the breakdown of CH4 and CO at high temperatures, the examination of the spent catalysts under optimal conditions yielded a smaller quantity of carbon of approximately 28.27% in comparison to the suboptimal conditions with 55.37%. Taylor & Francis 2024 Article PeerReviewed pdf en https://umpir.ump.edu.my/id/eprint/45289/1/Optimization%20of%20Cu-MnO%20catalyst%20for%20enhanced%20methane%20bi-reforming.pdf Irna Haslina, Ibrahim and Nor Shafiqah, Mohd Nasir and Nuremirah Syafiqah, Suhaimi and Li, Maoshua and Cuong Nguyen, Van and Sumaiya, Zainal Abidin (2024) Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production. Chemical Engineering Communications, 211 (11). pp. 1-20. ISSN 1563-5201. (Published) https://doi.org/10.1080/00986445.2024.2383577 https://doi.org/10.1080/00986445.2024.2383577 https://doi.org/10.1080/00986445.2024.2383577 |
| spellingShingle | QD Chemistry TP Chemical technology Irna Haslina, Ibrahim Nor Shafiqah, Mohd Nasir Nuremirah Syafiqah, Suhaimi Li, Maoshua Cuong Nguyen, Van Sumaiya, Zainal Abidin Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title | Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title_full | Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title_fullStr | Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title_full_unstemmed | Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title_short | Optimization of Cu/MnO catalyst for enhanced methane bi-reforming: A response surface methodology approach for sustainable syngas production |
| title_sort | optimization of cu/mno catalyst for enhanced methane bi-reforming: a response surface methodology approach for sustainable syngas production |
| topic | QD Chemistry TP Chemical technology |
| url | https://umpir.ump.edu.my/id/eprint/45289/ https://umpir.ump.edu.my/id/eprint/45289/ https://umpir.ump.edu.my/id/eprint/45289/ |