Photocatalysis has garnered significant attention for its potential in environmental remediation, energy conversion, and sustainable chemistry. Metal-organic frameworks (MOFs) have emerged as promising photocatalytic materials due to their tunable structures, high surface areas, and unique optical properties. Among them, a newly synthesized copper-benzene-1, 3, 5-tricarboxylic acid (Cu-BTC) MOF, [Cu3(C9H3O6)2].3H2O{18H2O} has shown remarkable potential as a photocatalyst. In this work, the synthesis and characterization of a novel [Cu3(C9H3O6)2].3H2O{18H2O} for its photocatalytic applications is described. The synthesis of [Cu3(C9H3O6)2].3H2O{18H2O} was achieved through a solvothermal method employing Copper (II) Nitrate trihydrate and benzene-1, 3, 5-tricarboxylic acid as precursors in a suitable solvent. The synthesized [Cu3(C9H3O6)2].3H2O{18H2O}) was characterized by Fourier transform infrared (FTIR), X-ray diffraction (XRD), Scanning electron microscope-energy dispersive X-ray spectroscopy (SEM-EDS), Single crystal and Thermogravimetric (TGA) analysis. The photocatalytic activity of ([Cu3(C9H3O6)2].3H2O{18H2O}) was evaluated in the transformation of Lissamine green SF (LGSF) and Tetraethylrhodamine (TeRh) under solar light irradiation. The intermediate compounds obtained during the transformation of LGSF under photocatalysis were detected using a gas chromatography-mass spectrometer (GC-MS). The recyclability of [Cu3(C9H3O6)2].3H2O{18H2O}was investigated to demonstrate its stability, robustness and potential for practical applications. Conclusively, the [Cu3(C9H3O6)2].3H2O{18H2O} was proven to be an effective catalyst in the mineralization of LGSF and TeRh.
Published in | Modern Chemistry (Volume 12, Issue 3) |
DOI | 10.11648/j.mc.20241203.11 |
Page(s) | 47-59 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Metal-organic Frameworks, Solvothermal Synthesis, Characterization, Adsorption, Light Irradiation
Cu-BTC, Cu-BTC based Photocatalyst | Pollutants | Pollutant concentration (ppm) | Catalyst loading (mg/L) | Irradiation time (min) | Efficiency (%) | Ref |
---|---|---|---|---|---|---|
HKUST-1 | Rhodamine B, Methylene blue | 10 | 120 | 5.8, 53 | 46 | |
MOF-199 | Methylene blue | 5 | 40 | 300 | 88.96 | 45 |
HKUST-1/PMS/Vis | Rhodamine B, Methylene blue | 10 | 120 | 95 | 46 | |
GO/ ZIF-8/HKUST-1 | Congo red | 50 | 500 | 60 | 91 | 47 |
CuO@HKUST− 1 | Methylene blue | 55 | 833.3 | 180 | 98 | 48 |
Cu-H3-btc–Ag2O | Orange G | 4.5 | 440 | 80 | 68.96 | 49 |
TiO2@HKUST-1 | Rhodamine B | 300 | 120 | 95.20 | 50 | |
HKUST-1(Cu)/polymer | Acid Black | 15 | 45 | 96 | 73 | |
ZnO@HKUST-1 | Rhodamine B | 20 | 320 | 45 | 97.4 | 51 |
Ag/Ag3PO4/HKUST-1 | Biotrack 405 Blue caspase-3 dye (PBS) | 1000 | 80 | 87 | 52 | |
Ag/HKUST-1/ g-C3N4 | Rhodamine B | 0.5 | 500 | 90 | 87.4 | 53 |
TiO2@HKUST-1 | Methylene blue | 20 | 500 | 60 | 91 | 54 |
GO− CS@Cu3(btc)2 | Methylene blue | 10 | 500 | 60 | 98 | 55 |
Lissamine green | ||||||
(LGSF) | Intermediates Percentage | |||||
(m/z 340) | (m/z 338) | (m/z 309) | (m/z 220) | (m/z 256) | (m/z 198) | |
Time | ||||||
30 | (84%) | (96%) | (64%) | (49%) | -- | -- |
60 | (61%) | (62%) | (41%) | (46%) | (59%) | (13%) |
90 | (21%) | (52%) | (34%) | (93%) | (74%) | (21%) |
120 | (13%) | (23%) | (42%) | (71%) | (84%) | (62%) |
150 | (17%) | (11%) | -- | (67%) | (91%) | (89%) |
180 | -- | -- | -- | (31%) | (71%) | (97%) |
Tetraethylrhodamine | ||||||
(TeRh) | Intermediates Percentage | |||||
(m/z 390) | (m/z 321) | (m/z 220) | (m/z 258) | (m/z 142) | ||
Time | ||||||
30 | (97%) | (54%) | (71%) | (13%) | -- | |
60 | (34%) | (66%) | (51%) | (37%) | (21%) | |
90 | (21%) | (42%) | (23%) | (42%) | (26%) | |
120 | (18%) | (35%) | -- | (78%) | (73%) | |
150 | (11%) | (19%) | (62%) | (74%) | (82%) | |
180 | -- | -- | (19%) | (93%) | (97%) |
CB | Conduction Band |
EDS | Energy Dispersive X-ray Spectroscopy |
FTIR | Fourier Transform Infrared |
HOMO | Highest Occupied Molecular Orbital |
LMCT | Ligand-to-Metal Charge Transfer |
LUMO | Lowest Unoccupied Molecular Orbital |
MOF | Metal-organic Framework |
SEM | Scanning Electron Microscope |
TGA | Thermogravimetric |
UV | Ultraviolet |
VB | Valence Band |
XRD | X-Ray Diffraction |
[1] | A. A. Atta-Eyison, R. Zugle, Characterization of newly synthesized photoactive [Cu3(C9H3O6)2].3H2O{18H2O} for the mineralization of Lissamine green SF (LGSF) and Tetraethylrhodamine (TeRh), Mendeley Data 1(2023). |
[2] | A. A Atta- Eyison, R. Zugle, Gas chromatography/mass spectrum (GC/MS) Results for the Mineralization of Lissamine Green SF and Tetraethylrhodamine.”, Mendeley Data, V1(2024) |
[3] | A. S Abdelmoaty, A. A. El-Beih, A. A. Hanna, Synthesis, characterization and antimicrobial activity of copper-metal organic framework (Cu-MOF) and its modification by melamine. Journal of Inorganic and Organometallic Polymers and Materials, 32(5), (2022), p. 1778-1785. |
[4] | E. C. Emenike, AGAdeniyi, PEOmuku, KCOkwu, KOIwuozor. Recent advances in nano-adsorbents for the sequestration of copper from water. Journal of Water Process Engineering. 1(47), (2022) p. 102-715. |
[5] | A. H. Shah, Z. U. Abideen, S. Maqsood, F. Rashid, R. Ullah, A. URehman, M. Dildar, M. Ahmad, K. Ullah, M. N. Rafi, F. Teng. Porous Cu-based metal organic framework (Cu-MOF) for highly selective adsorption of organic pollutants. Journal of Solid State Chemistry. Jun 1(322), (2023) p. 123-935. |
[6] | H. W. Haso, A. A. Dubale, M. A. Chimdesa, M. Atlabachew. High performance copper based metal organic framework for removal of heavy metals from wastewater. Frontiers in Materials. Mar 8(9) (2022) p. 840-806. |
[7] | A. Datta, M. Guleria, K. Kumar, J. Agarwal, R. Singh, V. Kaur, Copper (II) pseudoatrane appended heterobimetallic 2D-MOF: A multi-functional material with catalytic and sensing properties. Applied Organometallic Chemistry, 37(6) (2023) p. e7083. |
[8] | Y. Hua, X. Lv, Y. Cai, H. Liu, S. Li, Y. Wan, H. Wang, Highly selective and reproducible electroanalysis for histidine in blood with turn-on responses at a potential approaching zero using tetrahedral copper metal organic frameworks. Chemical Communications, 55(9), (2019) p. 1271-1274. |
[9] | R, A. Peralta, M. T. Huxley, J. Albalad, C. J. Sumby, C. J. Doonan, Single-Crystal-to-Single-Crystal Transformations of Metal–Organic-Framework-Supported, Site-Isolated Trigonal-Planar Cu (I) Complexes with Labile Ligands. Inorganic Chemistry, 60(16), (2021) p. 11775-11783. |
[10] | J. P. Vizuet, T. S. Howlett, A. L. Lewis, Z. D. Chroust, G. T. McCandless, K. J. Balkus Jr, Transition from a 1D coordination polymer to a mixed-linker layered MOF. Inorganic Chemistry, 58(8), (2019) p. 5031-5041. |
[11] | D. Xu, Y. Yang, K. Le, G. Wang, A. Ouyang, B. Li, W. Liu, L. Wu, Z. Wang, J. Liu, F. Wang, Bifunctional Cu9S5/C octahedral composites for electromagnetic wave absorption and supercapacitor applications. Chemical Engineering Journal, (2021) p. 417. |
[12] | H. X. Zhang, Q. L. Hong, J. Li, F. Wang, X. Huang, S. Chen, S. Chen, W. Tu, D. Yu, R. Xu, T. Zhou, J. Zhang, Isolated square-planar copper centre in boron imidazolate nanocages for photocatalytic reduction of CO2 to CO. Angewandte Chemie International Edition, 58(34), (2019) p. 11752-11756. |
[13] | J. Shen, X. Wang, L Zhang, Z. Yang, W. Yang, Z. Tian, J. Chen, T Tao. "Size-selective adsorption of methyl orange using a novel nano-composite by encapsulating HKUST-1 in hyper-crosslinked polystyrene networks." Journal of cleaner production, 184(2018) p. 949-958. |
[14] | W. W. Lestari, M Adreane, C Purnawan, H Fansuri, N Widiastuti, S B Rahardjo. "Solvothermal and electrochemical synthetic method of HKUST-1 and its methane storage capacity." In IOP Conference Series: Materials Science and Engineering, 107(1) (2016) p. 012030. |
[15] | X. He, Y. Jin, M. Jia, M. Jia, H. Wang, M. Imran. MOF-derived carbon coated Cu 3 P with Ni doping as advanced supercapacitor electrode materials. Sustainable Energy & Fuels. 6(23) (2022) p. 5360-5370. |
[16] | T. Baheri, Y. Yamini, M. Shamsayei, M. Tabibpour. Application of HKUST-1 metal-organic framework as coating for headspace solid-phase microextraction of some addictive drugs. Journal of Separation Science. 44(14) (2021) p. 281-423. |
[17] | M. Camats, D. Pla, M. Gómez. Copper nanocatalysts applied in coupling reactions: a mechanistic insight. Nanoscale. 13(45) (2021) p. 18817-18838. |
[18] | M. P. Ravele, O. A. Oyewo, D. C. Onwudiwe. Controlled Synthesis of CuS and Cu9S5 and Their Application in the Photocatalytic Mineralization of Tetracycline. Catalysts. 11(2021) p. 899. |
[19] | R. Kaur, A. Kaur, R. Kaur, S. Singh, M. S. Bhatti, A. Umar, S. Baskoutas, S. K. Kansal. Cu-BTC metal organic framework (MOF) derived Cu-doped TiO2 nanoparticles and their use as visible light active photocatalyst for the decomposition of ofloxacin (OFX) antibiotic and antibacterial activity. Advanced Powder Technology. 32(5) (2021) p. 1350-1361. |
[20] | Q. Wu, H. Ma, Y. Wang, J. Chen, J. Dai, X. Xu, X. Wu. Surface electron localization in Cu-MOF-bonded double-heterojunction Cu2O induces highly efficient photocatalytic CO2 reduction. ACS Applied Materials & Interfaces. 14(48) (2022) p. 54328-54337. |
[21] | Z. Wang, Y. Xu, C. Wang, L. Yue, T. Liu, Q. Lan, X. Cao, B. Xing. Photocatalytic inactivation of harmful algae Microcystis aeruginosa and degradation of microcystin by g-C3N4/Cu-MOF nanocomposite under visible light. Separation and Purification Technology. 313(2023) p. 123515. |
[22] | X. Su, T. Xu, R. Ye, C. Guo, S. M. Wabaidur, D. L. Chen, S. Aftab, Y Zhong, Y. Hu. One-pot solvothermal synthesis of In-doped amino-functionalized UiO-66 Zr-MOFs with enhanced ligand-to-metal charge transfer for efficient visible-light-driven CO2 reduction. Journal of Colloid and Interface Science. 646(2023) p. 129-140. |
[23] | S. Yang, W. Hu, J. Nyakuchena, C. Fiankor, C. Liu, E. D. Kinigstein, J. Zhang, X. Zhang, J. Huang. Unravelling a long-lived ligand-to-metal cluster charge transfer state in Ce–TCPP metal organic frameworks. Chemical Communications. 56(90) (2020) p. 13971-4. |
[24] | Y. Zhao, J. Wang, R. Pei. Guest Molecules with Amino and Sulfhydryl Groups Enhance Photoluminescence by Reducing the Intermolecular Ligand-to-Metal Charge Transfer Process of Metal–Organic Frameworks. Applied Sciences. 12(22) (2022) p. 11467. |
[25] | Y. Zhao, J. Wang, W, Zhu, L. Liu R. Pei. The modulation effect of charge transfer on photoluminescence in metal–organic frameworks. Nanoscale, 13(8) (2021), 4505-4511. |
[26] | K. An, H. Ren, D. Yang, Z. Zhao, Y. Gao, Y. Chen, J. Tan, W. Wang, Z. Jiang. Nitrogenase-inspired bimetallic metal organic frameworks for visible-light-driven nitrogen fixation. Applied Catalysis B: Environmental. 29(2021) p. 120167. |
[27] | P. P. Ferreira da Rosa, S. Miyazaki, H. Sakamoto, Y. Kitagawa, K. Miyata, T. Akama, M. Kobayashi, K. Fushimi, K. Onda, T. Taketsugu, Y. Hasegawa. Coordination geometrical effect on ligand-to-metal charge transfer-dependent energy transfer processes of luminescent Eu (III) complexes. The Journal of Physical Chemistry A. 125(1) (2021) p. 209-217. |
[28] | H. Zhang, S. Si, G. Zhai, Y. Li, Y. Liu, H. Cheng, Z. Wang, P. Wang, Z. Zheng, Y Dai, T. X. Liu, B. Huang, B. Huang,. The long-distance charge transfer process in ferrocene-based MOFs with FeO6 clusters boosts photocatalytic CO2 chemical fixation. Applied Catalysis B: Environmental. (2023) p. 122909. |
[29] | S. B. Chanu, M. K. Raza, D. Musib, M. Pal, M. Pal, M. Roy. Potent Photochemotherapeutic Activity of Iron (III) Complexes on Visible Light-induced Ligand to Metal Charge Transfer. Chemistry Letters. 49(6) (2020) p. 724-727. |
[30] | R. Das, S. S. Manna, B. Pathak, C. M. Nagaraja. Strategic design of Mg-centered porphyrin metal–organic framework for efficient visible light-promoted fixation of CO2 under ambient conditions: combined experimental and theoretical investigation. ACS applied materials & interfaces. 14(29) (2022) p. 33285-33296. |
[31] | R. Yin, Y. Chen, J. Hu, G. Lu, L. Zeng, W. Choi, M. Zhu. Complexes of Fe (III)-organic pollutants that directly activate Fenton-like processes under visible light. Applied Catalysis B: Environmental. 283(2021) p. 119663. |
[32] | Q. Wang, Q. Gao, A. M. Al-Enizi, A. Nafady, S. Ma. Recent advances in MOF-based photocatalysis: environmental remediation under visible light. Inorganic Chemistry Frontiers. 7(2) (2020) p. 300-339. |
[33] | S. Gautam, H. Agrawal, M. Thakur, A. Akbari, H. Sharda, R. Kaur, M. Amini. Metal oxides and metal-organic frameworks for the photocatalytic degradation: A review. Journal of Environmental Chemical Engineering. 8(3) (2020) p. 103726. |
[34] | M. T. Hang, Y. Cheng, Y. T. Wang, H. Li, M. Q. Zheng, M. Y. He, Q. Chen, Z. H. Zhang. Rational synthesis of isomorphic rare earth metal-organic framework materials for simultaneous adsorption and photocatalytic degradation of organic dyes in water. CrystEngComm. 24(3) (2022) p. 552-559. |
[35] | C. Hou, X. Yuan, M. Niu, Y. Li, L. Wang, M. Zhang. In situ composite of Co-MOF on a Ti-based material for visible light multiphase catalysis: synthesis and the photocatalytic degradation mechanism. New Journal of Chemistry. 46(23) (2022) p. 11341-11349. |
[36] | X. Zhang, J. Wang, X. X. Dong, Y. K. Lv. Functionalized metal-organic frameworks for photocatalytic degradation of organic pollutants in environment. Chemosphere. 242(2020) p. 125144. |
[37] | W. Huang, X. Wang, W. Zhang, S. Zhang, Y. Tian, Z. Chen, W. Fang, J. Ma Intraligand charge transfer boosts visible-light-driven generation of singlet oxygen by metal-organic frameworks. Applied Catalysis B: Environmental. 273(2020) p. 119087. |
[38] | G. Ramalingam, R. Pachaiappan, P. S. Kumar, S. Dharani, S. Rajendran, D. V. N. Vo, T. K. Hoang.. Hybrid metal organic frameworks as an Exotic material for the photocatalytic degradation of pollutants present in wastewater: a review. Chemosphere. 288(2022) p. 132448. |
[39] | L. Wang, X. Li, B. Yang, K. Xiao, H. Duan, H. Zhao. The chemical stability of metal-organic frameworks in water treatments: Fundamentals, effect of water matrix and judging methods. Chemical Engineering Journal. 450(2022) p. 138215. |
[40] | W. Zhang, W. Huang, J. Jin, Y. Gan, S. Zhang. Oxygen-vacancy-mediated energy transfer for singlet oxygen generation by diketone-anchored MIL-125. Applied Catalysis B: Environmental. 292(2021) p. 120197. |
[41] | M. Endashaw, T. Girma. Review on the removal of dyes by photodegradation using metal-organic frameworks under light irradiation. Chemistry and Materials Research, 12(1) (2020) p. 14-21. |
[42] | G. Su, T. Feng, Z. Huang, Y. Zheng, W. Zhang, G. Liu, W. Wang, H. Wei, L, Dang. MOF derived hollow CuO/ZnO nanocages for the efficient and rapid degradation of fluoroquinolones under natural sunlight. Chemical Engineering Journal. 436(2022) p. 135119. |
[43] | S. Li, S. Shan, S. Chen, H. Li, Z. Li, Y. Liang, J. Fei, L. Xie, J. Li. Photocatalytic degradation of hazardous organic pollutants in water by Fe-MOFs and their composites: A review. Journal of Environmental Chemical Engineering. 9(5) (2021) p. 105967. |
[44] | C. Yue, L. Chen, H. Zhang, J. Huang, H. Jiang, H. Li, S. Yang. Metal-organic framework-based materials: emerging high-efficiency catalysts for the heterogeneous photocatalytic degradation of pollutants in water. Environmental Science: Water Research & Technology. 9(3) (2023) p. 669-695. |
[45] | D. Garg, H. Rekhi, H. Kaur, K. Singh, A. K. Malik. A novel method for the synthesis of MOF-199 for sensing and photocatalytic applications. Journal of Fluorescence. 32(3) (2022) p. 1171-1188. |
[46] | J. Zhang, C. Su, X. Xie, P. Liu, M. E. Huq. Enhanced visible light photocatalytic degradation of dyes in aqueous solution activated by HKUST-1: performance and mechanism. RSC advances. 10(61) (2020) p. 37028-37034. |
[47] | R. Ediati, L. L. Zulfa, I Maulidah, D. O. Sulistiono, H. Fansuri, A. Rosyidah, F. Martak, D. Hartanto, M. A. Abdullah, W. P. Utomo, E. N. Kusumawati. Addition of graphene oxide to ZIF-8/HKUST-1 composite for enhanced adsorptive and photocatalytic removal of congo red in wastewater. South African Journal of Chemical Engineering. 46(1) (2023) p. 132-142. |
[48] | M. Jin, X. Qian, J. Gao, J. Chen, D. K. Hensley, H. C. Ho, R. J. Percoco, C. M. Ritzi, Y. Yue. Solvent-free synthesis of CuO/HKUST-1 composite and its photocatalytic application. Inorganic Chemistry. 58(13) (2019) p. 8332-8338. |
[49] | N. Tabatabaei, K. Dashtian, M. Ghaedi, M. M. Sabzehmeidani, E. Ameri. Novel visible light-driven Cu-based MOFs/Ag 2 O composite photocatalysts with enhanced photocatalytic activity toward the degradation of orange G: their photocatalytic mechanism and optimization study. New Journal of Chemistry. 42(12) (2018) p. 9720-9734. |
[50] | Y. Qiao, C. Sun, J. Jian, T. Zhou, X. Xue, J. Shi, G. Che, G. Liao. Efficient removal of organic pollution via photocatalytic degradation over a TiO2@ HKUST-1 yolk-shell nanoreactor. Journal of Molecular Liquids. 385(2023) p. 122383. |
[51] | S. Roy, J. Darabdhara, M. Ahmaruzzaman. ZnO-based Cu metal–organic framework (MOF) nanocomposite for boosting and tuning the photocatalytic degradation performance. Environmental Science and Pollution Research. (42) (2023) p. 95673-95691. |
[52] | F. A. Sofi, K. Majid, O. Mehraj. The visible light driven copper based metal-organic-framework heterojunction: HKUST-1@ Ag-Ag3PO4 for plasmon enhanced visible light photocatalysis. Journal of Alloys and Compounds. 737(2018) p. 798-808. |
[53] | Y. Qiao, Q. Han, D. Li, H. Li, B. Wei, G. Che, W. Jiang, W. Guan. Construction of novel Ag/HKUST-1/gC 3 N 4 towards enhanced photocatalytic activity for the degradation of pollutants under visible light. RSC advances. 9(71) (2019) p. 41591-41602. |
[54] | M. Xiaobo, L. Xinyu, Z. Jie, H. Xiaoxian, Y. Weichun. Heterostructured TiO2@ HKUST-1 for the enhanced removal of methylene blue by integrated adsorption and photocatalytic degradation. Environmental Technology. 4(26) (2021) p. 4134-4414. |
[55] | M. S. Samuel, S Suman, E. Selvarajan, T. Mathimani, A. Pugazhendhi. Immobilization of Cu3(btc) 2 on graphene oxide-chitosan hybrid composite for the adsorption and photocatalytic degradation of methylene blue. Journal of Photochemistry and Photobiology B: Biology. 204(2020) p. 111809. |
[56] | S. Roy, J. Darabdhara, M. Ahmaruzzaman. Recent advances of Copper-BTC metal-organic frameworks for efficient degradation of organic dye-polluted wastewater: Synthesis, Mechanistic Insights and Future Outlook. Journal of Hazardous Materials Letters. 23(2023) p. 100094. |
[57] | L. Yang, G. L. Ruess, M. A. Carreon, Cu, Al and Ga based metal organic framework catalysts for the decarboxylation of oleic acid. Catalysis Science & Technology, 5(5), (2015) p. 2777-2782. |
[58] | A. K. Kar, R. Srivastava, An efficient and sustainable catalytic reduction of carbon–carbon multiple bonds, aldehydes, and ketones using a Cu nanoparticle decorated metal organic framework. New Journal of Chemistry, 42(12), (2018) p. 9557-9567. |
[59] | R. Nivetha, A. Sajeev, A. M Paul, K. Gothandapani, S. Gnanasekar, P. Bhardwaj, G. Jacob, R. Sellappan, V. Raghavan, K. Chandar, S. Pitchaimuthu, S. K Jeong, A. N. Grace, Cu based Metal Organic Framework (Cu-MOF) for electrocatalytic hydrogen evolution reaction. Materials Research Express, 7(11), (2020) p. 114001. |
[60] | C. Ardila-Suárez, A. M. Díaz-Lasprilla, L. A. Díaz-Vaca, P. B. Balbuena, V. G. Baldovino-Medrano, G. E. Ramírez-Caballero, Synthesis, characterization, and post-synthetic modification of a micro/ mesoporous zirconium–tricarboxylate metal–organic framework: Towards the addition of acid active sites. CrystEngComm, 21(19), (2019) p. 3014-3030. |
[61] | X. Guo, C. Lin, M. Zhang, X. Duan, X. Dong, D. Sun, T. You, 2D/3D Copper-Based Metal-Organic Frameworks for Electrochemical Detection of Hydrogen Peroxide. Frontiers in Chemistry, 9, (2021) p. 743637. |
[62] | J. Al Cheikh, A. Villagra, A. Ranjbari, A. Pradon, M. Antuch, D. Dragoe, L. Assaud, Engineering a cobalt clathrochelate/ glassy carbon interface for the hydrogen evolution reaction. Applied Catalysis B: Environmental, 250, (2019) p. 292-300. |
[63] | A. B. D. Nandiyanto, R. Oktiani, R. Ragadhita, How to read and interpret FTIR spectroscope of organic material. Indonesian Journal of Science and Technology, 4(1), (2019) p. 97-118. |
[64] | S. Nzikayel, I. J. Akpan, E. C. Adams, Synthesis, ftir and electronic spectra studies of metal (ii) complexes of pyrazine-2-carboxylic acid derivative. Medicinal Chemistry, 7(11), (2017) p. 2161-444. |
[65] | G. M. Sheldrick, Crystal structure refinement with ShelXL, Acta Cryst. C71(2015a) p. 3-8. |
[66] | G. M. Sheldrick, ShelXT-Integrated space-group and crystal-structure determination, Acta Cryst. A71(2015b) p. 3-8. |
[67] | A. S. Mukasyan, DTA/TGA-based methods. In Concise Encyclopedia of Self-Propagating High-Temperature Synthesis. Elsevier. (2017) p. 93-95. |
[68] | F. Yakuphanoglu, Thermal analysis methods used in solid state physics and chemistry to obtain kinetics and thermodynamics parameters of solid materials by TGA, DTA and DSC analyses. Journal of Materials and Electronic Devices, 1(1), (2019) p. 17-23. |
[69] | A. A. Scharnberg, A. C. De Loreto, A. K. Alves. Optical and structural characterization of Bi2FexNbO7 nanoparticles for environmental applications. Emerging Science Journal. 4(1) (2020) p. 11-17. |
[70] | H. Siddiqui, M. S. Qureshi, F. Z. Haque. pH-dependent single-step rapid synthesis of CuO nanoparticles and their optical behavior. Optics and Spectroscopy. 123(2017) p. 903-912. |
[71] | W. Brostow, G. Granowski, N. Hnatchuk, J. Sharp, J. B. White. Thermoelectric phenomena. J. Mater. Educ. 36(5-6) (2014) p. 175-186. |
[72] | F. Roccaforte, G. Brezeanu, P. M. Gammon, F. Giannazzo, S. Rascunà, M. Saggio, M. Schottky. contacts to silicon carbide: Physics, technology and applications. Advancing Silicon Carbide Electronics Technology, I: Metal Contacts to Silicon Carbide: Physics, Technology, Applications. (2018) p. 9781945291852-3. |
[73] | C. Brahmi, M. Benltifa, C. Vaulot, L. Michelin, F. Dumur, F. Millange, M. Frigoli, Airoudj A, Morlet-Savary F, Bousselmi L, Lalevée J. New hybrid MOF/polymer composites for the photodegradation of organic dyes. European Polymer Journal. 154(2021) p. 110560. |
APA Style
Atta-Eyison, A. A., Zugle, R. (2024). Synthesis and Characterization of Highly Efficient Cu-BTC MOF, ([Cu3(C9H3O6)2].3H2O{18H2O}) Photocatalyst for the Adsorptive Transformation of Coloured Organic Pollutants in Water. Modern Chemistry, 12(3), 47-59. https://doi.org/10.11648/j.mc.20241203.11
ACS Style
Atta-Eyison, A. A.; Zugle, R. Synthesis and Characterization of Highly Efficient Cu-BTC MOF, ([Cu3(C9H3O6)2].3H2O{18H2O}) Photocatalyst for the Adsorptive Transformation of Coloured Organic Pollutants in Water. Mod. Chem. 2024, 12(3), 47-59. doi: 10.11648/j.mc.20241203.11
AMA Style
Atta-Eyison AA, Zugle R. Synthesis and Characterization of Highly Efficient Cu-BTC MOF, ([Cu3(C9H3O6)2].3H2O{18H2O}) Photocatalyst for the Adsorptive Transformation of Coloured Organic Pollutants in Water. Mod Chem. 2024;12(3):47-59. doi: 10.11648/j.mc.20241203.11
@article{10.11648/j.mc.20241203.11, author = {Aba Akebi Atta-Eyison and Ruphino Zugle}, title = {Synthesis and Characterization of Highly Efficient Cu-BTC MOF, ([Cu3(C9H3O6)2].3H2O{18H2O}) Photocatalyst for the Adsorptive Transformation of Coloured Organic Pollutants in Water }, journal = {Modern Chemistry}, volume = {12}, number = {3}, pages = {47-59}, doi = {10.11648/j.mc.20241203.11}, url = {https://doi.org/10.11648/j.mc.20241203.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.mc.20241203.11}, abstract = {Photocatalysis has garnered significant attention for its potential in environmental remediation, energy conversion, and sustainable chemistry. Metal-organic frameworks (MOFs) have emerged as promising photocatalytic materials due to their tunable structures, high surface areas, and unique optical properties. Among them, a newly synthesized copper-benzene-1, 3, 5-tricarboxylic acid (Cu-BTC) MOF, [Cu3(C9H3O6)2].3H2O{18H2O} has shown remarkable potential as a photocatalyst. In this work, the synthesis and characterization of a novel [Cu3(C9H3O6)2].3H2O{18H2O} for its photocatalytic applications is described. The synthesis of [Cu3(C9H3O6)2].3H2O{18H2O} was achieved through a solvothermal method employing Copper (II) Nitrate trihydrate and benzene-1, 3, 5-tricarboxylic acid as precursors in a suitable solvent. The synthesized [Cu3(C9H3O6)2].3H2O{18H2O}) was characterized by Fourier transform infrared (FTIR), X-ray diffraction (XRD), Scanning electron microscope-energy dispersive X-ray spectroscopy (SEM-EDS), Single crystal and Thermogravimetric (TGA) analysis. The photocatalytic activity of ([Cu3(C9H3O6)2].3H2O{18H2O}) was evaluated in the transformation of Lissamine green SF (LGSF) and Tetraethylrhodamine (TeRh) under solar light irradiation. The intermediate compounds obtained during the transformation of LGSF under photocatalysis were detected using a gas chromatography-mass spectrometer (GC-MS). The recyclability of [Cu3(C9H3O6)2].3H2O{18H2O}was investigated to demonstrate its stability, robustness and potential for practical applications. Conclusively, the [Cu3(C9H3O6)2].3H2O{18H2O} was proven to be an effective catalyst in the mineralization of LGSF and TeRh. }, year = {2024} }
TY - JOUR T1 - Synthesis and Characterization of Highly Efficient Cu-BTC MOF, ([Cu3(C9H3O6)2].3H2O{18H2O}) Photocatalyst for the Adsorptive Transformation of Coloured Organic Pollutants in Water AU - Aba Akebi Atta-Eyison AU - Ruphino Zugle Y1 - 2024/09/11 PY - 2024 N1 - https://doi.org/10.11648/j.mc.20241203.11 DO - 10.11648/j.mc.20241203.11 T2 - Modern Chemistry JF - Modern Chemistry JO - Modern Chemistry SP - 47 EP - 59 PB - Science Publishing Group SN - 2329-180X UR - https://doi.org/10.11648/j.mc.20241203.11 AB - Photocatalysis has garnered significant attention for its potential in environmental remediation, energy conversion, and sustainable chemistry. Metal-organic frameworks (MOFs) have emerged as promising photocatalytic materials due to their tunable structures, high surface areas, and unique optical properties. Among them, a newly synthesized copper-benzene-1, 3, 5-tricarboxylic acid (Cu-BTC) MOF, [Cu3(C9H3O6)2].3H2O{18H2O} has shown remarkable potential as a photocatalyst. In this work, the synthesis and characterization of a novel [Cu3(C9H3O6)2].3H2O{18H2O} for its photocatalytic applications is described. The synthesis of [Cu3(C9H3O6)2].3H2O{18H2O} was achieved through a solvothermal method employing Copper (II) Nitrate trihydrate and benzene-1, 3, 5-tricarboxylic acid as precursors in a suitable solvent. The synthesized [Cu3(C9H3O6)2].3H2O{18H2O}) was characterized by Fourier transform infrared (FTIR), X-ray diffraction (XRD), Scanning electron microscope-energy dispersive X-ray spectroscopy (SEM-EDS), Single crystal and Thermogravimetric (TGA) analysis. The photocatalytic activity of ([Cu3(C9H3O6)2].3H2O{18H2O}) was evaluated in the transformation of Lissamine green SF (LGSF) and Tetraethylrhodamine (TeRh) under solar light irradiation. The intermediate compounds obtained during the transformation of LGSF under photocatalysis were detected using a gas chromatography-mass spectrometer (GC-MS). The recyclability of [Cu3(C9H3O6)2].3H2O{18H2O}was investigated to demonstrate its stability, robustness and potential for practical applications. Conclusively, the [Cu3(C9H3O6)2].3H2O{18H2O} was proven to be an effective catalyst in the mineralization of LGSF and TeRh. VL - 12 IS - 3 ER -