Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2020, Cilt: 16 Sayı: 3, 285 - 291, 29.09.2020
https://doi.org/10.18466/cbayarfbe.742711

Öz

Kaynakça

  • 1. Xu, YL, Shi, XF, Hua, R, Zhang, R, Yao YJ, Zhao, B, Liu, T, Zheng, JZ, Lu, G. 2020. Remarkably catalytic activity in reduction of 4-nitrophenol and methylene blue by Fe3O4@COF supported noble metal nanoparticles. Applied Catalysis B: Environmental; 260.
  • 2. Yang, YT, Wang, TA, Jing, XF, Zhu, GS. 2019. Phosphine-based porous aromatic frameworks for gold nanoparticle immobilization with superior catalytic activities. Journal of Materials Chemistry A; 7(16): 10004-10009.
  • 3. Dayan, S, Arslan, F, Ozpozan, NK. 2015. Ru(II) impregnated Al2O3, Fe3O4, SiO2 and N-ecoordinate ruthenium(II) arene complexes: Multifunctional catalysts in the hydrogenation of nitroarenes and the transfer hydrogenation of aryl ketones. Applied Catalysis B: Environmental; 164: 305-315.
  • 4. Dell'Anna, MM, Intini S, Romanazzi, G, Rizzuti, A, Leonelli, C, Piccinni, F, Mastrorilli, P. 2014. Polymer supported palladium nanocrystals as efficient and recyclable catalyst for the reduction of nitroarenes to anilines under mild conditions in water. Journal of Molecular Catalysis A; 395: 307-314.
  • 5. Hu, XW, Long, Y, Fan, MY, Yuan, M, Zhao, H, Ma, JT, Dong, ZP. 2019. Two-dimensional covalent organic frameworks as self-template derived nitrogen-doped carbon nanosheets for eco-friendly metal-free catalysis. Applied Catalysis B: Environmental; 244: 25-35.
  • 6. Shokouhimehr, M, Kim, T, Jun, SW, Shin, K, Jang, Y, Kim, BH, Kim, J, Hyeon, T. 2014. Magnetically separable carbon nanocomposite catalysts for efficient nitroarene reduction and Suzuki reactions. Applied Catalysis A: General; 476: 133-139.
  • 7. Das, P, Ghosh, S, Baskey, M. 2019. Heterogeneous catalytic reduction of 4-nitroaniline by RGO-Ni nanocomposite for water resource management. Journal of Materials Science: Materials in Electronics; 30: 19731-19737.
  • 8. Qu, YM, Chen, T. 2020. Fullerene derivative supported Ni for hydrogenation of nitrobenzene: Effect of functional group of fullerene derivative. Chemical Engineering Journal; 382: 122911.
  • 9. Liu, Q, Tadrent, S, Proust, C, Gomez, F, Khelfa, A, Luart, D, Len, C. 2020. Theoretical analysis of the "green" synthesis of aniline by reduction of nitrobenzene. Chemical Engineering Science; 211: 115275.
  • 10. Du, JT, Shi, J, Sun, Q, Wang, D, Wu, H, Wang, JX, Chen, JF. 2020. High-gravity-assisted preparation of aqueous dispersions of monodisperse palladium nanocrystals as pseudohomogeneous catalyst for highly efficient nitrobenzene reduction. Chemical Engineering Journal; 382: 122883.
  • 11. Baloch, GNL, Mahesar, SA, Khan, S, Niisar, J, Sherazi, STH. 2020. Ranolazine-functionalized CuO NPs: efficient homogeneous and heterogeneous catalysts for reduction of 4-nitrophenol, Turkish Journal of Chemistry; 44 (1): 168-179.
  • 12. Dayan, S, Altinkaynak, C, Kayaci, N, Dogan, SD, Özdemir, N, Ozpozan, NK. 2020. Hybrid nanoflowers bearing tetraphenylporphyrin assembled on copper(II) or cobalt(II) inorganic material: A green efficient catalyst for hydrogenation of nitrobenzenes in water. Applied Organometallic Chemistry; 34 (3): e5381.
  • 13. Hira, SA, Nallal, M, Park, KH. 2019. Fabrication of PdAg nanoparticle infused metal-organic framework for electrochemical and solution-chemical reduction and detection of toxic 4-nitrophenol. Sensors and Actuators B: Chemical; 298: 126861.
  • 14. Shahini, P, Ashkarran, AA. 2018. Immobilization of plasmonic Ag-Au NPs on the TiO2 nanofibers as an efficient visible-light photocatalyst. Colloids and Surfaces A; 537: 155-162.
  • 15. Mahnaz, F, Mostafa-Al-Momin, M, Rubel, M, Ferdous, M, Azam, MS. 2019. Mussel-inspired immobilization of Au on bare and graphene-wrapped Ni nanoparticles toward highly efficient and easily recyclable catalysts. RSC Advances; 9 (52): 30358-30369.
  • 16. Li, CX, Wang, JK, Jiang, ZH, Hu, PG. 2015. Co/Cu2O assisted growth of graphene oxide on carbon nanotubes and its water splitting activities. New Journal of Chemistry; 39 (6): 4562-4567.
  • 17. Jiang, JW, Lim, YS, Park, S, Kim, SH, Yoon, S, Piao, L. 2017. Hollow porous Cu particles from silica-encapsulated Cu2O nanoparticle aggregates effectively catalyze 4-nitrophenol reduction. Nanoscale; 9 (11): 3873-3880.
  • 18. Taherinia, Z, Ghorbani-Choghamarani, A. 2019. Cu(I)-PNF, an organic-based nanocatalyst, catalyzed C-O and C-S cross-coupling reactions. Canadian Journal of Chemistry; 97 (1): 46-52.
  • 19. Singh, G, Rani, S, Arora, A, Sanchita, Duggal, H, Mehta, D. 2017. Organic-inorganic nano-hybrid decorated by copper (II) incarceration: A versatile catalytic assembly for the swift reduction of aromatic nitro and dye compounds. Molecular Catalysis; 431: 15-26.
  • 20. Ahmadi, A, Sedaghat, T, Motamedi, H, Azadi. R. 2020. Anchoring of Cu (II)-Schiff base complex on magnetic mesoporous silica nanoparticles: catalytic efficacy in one-pot synthesis of 5-substituted-1H-tetrazoles, antibacterial activity evaluation and immobilization of alpha-amylase. Applied Organometallic Chemistry; 34 (5) e5572.
  • 21. Tahmasbi, L, Sedaghat, T, Motamedi, H, Kooti, M. 2018. Mesoporous silica nanoparticles supported copper(II) and nickel(II) Schiff base complexes: Synthesis, characterization, antibacterial activity and enzyme immobilization. Journal of Solid State Chemistry; 258: 517-525.
  • 22. Ramu, VG, Bordoloi, A, Nagaiah, TC, Schuhmann, W, Muhler, M, Cabrele, C. 2012. Copper nanoparticles stabilized on nitrogen-doped carbon nanotubes as efficient and recyclable catalysts for alkyne/aldehyde/cyclic amine A(3)-type coupling reactions. Applied Catalysis A: General; 431: 88-94.
  • 23. Dayan, S, Kayaci, N, Dayan, O, Ozdemir, N, Ozpozan, NK. 2020. Nickel (II) complex [NiCl2(DMF)2L2] bearing diaminobenzene and sulfonamide: Crystal structure and catalytic application in the reduction of nitrobenzenes. Polyhedron; 175: 114181.
  • 24. Baghbamidi, SE, Hassankhani, A, Sanchooli, E, Sadeghzadeh, SM. 2018. The reduction of 4-nitrophenol and 2-nitroaniline by palladium catalyst based on a KCC-1/IL in aqueous solution. Applied Organometallic Chemistry; 32 (4): e4251.
  • 25. Kamal, T. 2019. Aminophenols formation from nitrophenols using agar biopolymer hydrogel supported CuO nanoparticles catalyst. Polymer Testing; 77: 105896.
  • 26. Mahmoud, ME, Amira, MF, Abouelanwar, ME, Seleim, SM. 2020. Catalytic reduction of nitrophenols by a novel assembled nanocatalyst based on zerovalent copper-nanopolyaniline-nanozirconium silicate. Journal of Molecular Liquids; 299: 112192.
  • 27. Li, ML, Chen, GF. 2013. Revisiting catalytic model reaction p-nitrophenol/NaBH4 using metallic nanoparticles coated on polymeric spheres, Nanoscale; 5 (23):11919-11927.
  • 28. Sun, HZ, Zelekew, OA, Chen, XY, Guo, YB, Kuo DH, Lu, QX, Lin, JG. 2019. A noble bimetal oxysulfide CuVOS catalyst for highly efficient catalytic reduction of 4-nitrophenol and organic dyes. RSC Advances; 9 (55): 31828-31839.
  • 29. Ahsan, MA, Jabbari, V, El-Gendy, AA, Curry, ML, Noveron, JC. 2019. Ultrafast catalytic reduction of environmental pollutants in water via MOF-derived magnetic Ni and Cu nanoparticles encapsulated in porous carbon. Applied Surface Science; 497: 143608.
  • 30. Liang, X, Chen, XW, Xiang, ZL, Yan, R, Xi, H, Bian, T, Zhang, JJ, Zhao, JX, Cai, QH, Wang, HX. 2018. Design and synthesis of surface-controlled CuOx/rGO nanocomposites with unusually high efficiency in catalytic conversion of organic reactants in the presence of NaBH4. Applied Surface Science; 459: 716-722.

Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes

Yıl 2020, Cilt: 16 Sayı: 3, 285 - 291, 29.09.2020
https://doi.org/10.18466/cbayarfbe.742711

Öz

The N-(3-((2-hydroxybenzylidene)amino)phenyl)benzamide Schiff base ligand (L) was synthesized, characterized, and immobilized on the fullerene material with reduction copper material. The result nanocomposite Cu/Ligand@Fullerene (M1) was characterized by FE-SEM EDX, EDX mapping, FT-IR, and XRD techniques and tested as a catalyst for reduction of nitrophenols (2-nitrophenol (2-NP), 4-nitrophenol (4-NP)) and organic dyes (methylene blue (M.B.), Rhodamine B (Rh. B)) under ambient temperature in water. The catalytic conversions and the reaction rate constant per total weight of the M1 catalyst were recorded as 89.9% and 2.71E+00 at 300 s for 2-nitrophenol, 97.9% and 5.12E+00 at 300 s for 4-nitrophenol, 90.6% and 2.72E+01 at 360 s for Rhodamine B, and 98.3% and 2.63E+00 at 60 s for methylene blue. For 4-NP, the reusability study was carried out as five cycles with 97.9%, 97.7%, 97.7%, 97.3%, and 87.3% conversions, respectively. The fabricated Cu/Ligand@Fullerene (M1) nanocomposite has good catalytic efficiency and reusability, low cost, and easy to produce.

Kaynakça

  • 1. Xu, YL, Shi, XF, Hua, R, Zhang, R, Yao YJ, Zhao, B, Liu, T, Zheng, JZ, Lu, G. 2020. Remarkably catalytic activity in reduction of 4-nitrophenol and methylene blue by Fe3O4@COF supported noble metal nanoparticles. Applied Catalysis B: Environmental; 260.
  • 2. Yang, YT, Wang, TA, Jing, XF, Zhu, GS. 2019. Phosphine-based porous aromatic frameworks for gold nanoparticle immobilization with superior catalytic activities. Journal of Materials Chemistry A; 7(16): 10004-10009.
  • 3. Dayan, S, Arslan, F, Ozpozan, NK. 2015. Ru(II) impregnated Al2O3, Fe3O4, SiO2 and N-ecoordinate ruthenium(II) arene complexes: Multifunctional catalysts in the hydrogenation of nitroarenes and the transfer hydrogenation of aryl ketones. Applied Catalysis B: Environmental; 164: 305-315.
  • 4. Dell'Anna, MM, Intini S, Romanazzi, G, Rizzuti, A, Leonelli, C, Piccinni, F, Mastrorilli, P. 2014. Polymer supported palladium nanocrystals as efficient and recyclable catalyst for the reduction of nitroarenes to anilines under mild conditions in water. Journal of Molecular Catalysis A; 395: 307-314.
  • 5. Hu, XW, Long, Y, Fan, MY, Yuan, M, Zhao, H, Ma, JT, Dong, ZP. 2019. Two-dimensional covalent organic frameworks as self-template derived nitrogen-doped carbon nanosheets for eco-friendly metal-free catalysis. Applied Catalysis B: Environmental; 244: 25-35.
  • 6. Shokouhimehr, M, Kim, T, Jun, SW, Shin, K, Jang, Y, Kim, BH, Kim, J, Hyeon, T. 2014. Magnetically separable carbon nanocomposite catalysts for efficient nitroarene reduction and Suzuki reactions. Applied Catalysis A: General; 476: 133-139.
  • 7. Das, P, Ghosh, S, Baskey, M. 2019. Heterogeneous catalytic reduction of 4-nitroaniline by RGO-Ni nanocomposite for water resource management. Journal of Materials Science: Materials in Electronics; 30: 19731-19737.
  • 8. Qu, YM, Chen, T. 2020. Fullerene derivative supported Ni for hydrogenation of nitrobenzene: Effect of functional group of fullerene derivative. Chemical Engineering Journal; 382: 122911.
  • 9. Liu, Q, Tadrent, S, Proust, C, Gomez, F, Khelfa, A, Luart, D, Len, C. 2020. Theoretical analysis of the "green" synthesis of aniline by reduction of nitrobenzene. Chemical Engineering Science; 211: 115275.
  • 10. Du, JT, Shi, J, Sun, Q, Wang, D, Wu, H, Wang, JX, Chen, JF. 2020. High-gravity-assisted preparation of aqueous dispersions of monodisperse palladium nanocrystals as pseudohomogeneous catalyst for highly efficient nitrobenzene reduction. Chemical Engineering Journal; 382: 122883.
  • 11. Baloch, GNL, Mahesar, SA, Khan, S, Niisar, J, Sherazi, STH. 2020. Ranolazine-functionalized CuO NPs: efficient homogeneous and heterogeneous catalysts for reduction of 4-nitrophenol, Turkish Journal of Chemistry; 44 (1): 168-179.
  • 12. Dayan, S, Altinkaynak, C, Kayaci, N, Dogan, SD, Özdemir, N, Ozpozan, NK. 2020. Hybrid nanoflowers bearing tetraphenylporphyrin assembled on copper(II) or cobalt(II) inorganic material: A green efficient catalyst for hydrogenation of nitrobenzenes in water. Applied Organometallic Chemistry; 34 (3): e5381.
  • 13. Hira, SA, Nallal, M, Park, KH. 2019. Fabrication of PdAg nanoparticle infused metal-organic framework for electrochemical and solution-chemical reduction and detection of toxic 4-nitrophenol. Sensors and Actuators B: Chemical; 298: 126861.
  • 14. Shahini, P, Ashkarran, AA. 2018. Immobilization of plasmonic Ag-Au NPs on the TiO2 nanofibers as an efficient visible-light photocatalyst. Colloids and Surfaces A; 537: 155-162.
  • 15. Mahnaz, F, Mostafa-Al-Momin, M, Rubel, M, Ferdous, M, Azam, MS. 2019. Mussel-inspired immobilization of Au on bare and graphene-wrapped Ni nanoparticles toward highly efficient and easily recyclable catalysts. RSC Advances; 9 (52): 30358-30369.
  • 16. Li, CX, Wang, JK, Jiang, ZH, Hu, PG. 2015. Co/Cu2O assisted growth of graphene oxide on carbon nanotubes and its water splitting activities. New Journal of Chemistry; 39 (6): 4562-4567.
  • 17. Jiang, JW, Lim, YS, Park, S, Kim, SH, Yoon, S, Piao, L. 2017. Hollow porous Cu particles from silica-encapsulated Cu2O nanoparticle aggregates effectively catalyze 4-nitrophenol reduction. Nanoscale; 9 (11): 3873-3880.
  • 18. Taherinia, Z, Ghorbani-Choghamarani, A. 2019. Cu(I)-PNF, an organic-based nanocatalyst, catalyzed C-O and C-S cross-coupling reactions. Canadian Journal of Chemistry; 97 (1): 46-52.
  • 19. Singh, G, Rani, S, Arora, A, Sanchita, Duggal, H, Mehta, D. 2017. Organic-inorganic nano-hybrid decorated by copper (II) incarceration: A versatile catalytic assembly for the swift reduction of aromatic nitro and dye compounds. Molecular Catalysis; 431: 15-26.
  • 20. Ahmadi, A, Sedaghat, T, Motamedi, H, Azadi. R. 2020. Anchoring of Cu (II)-Schiff base complex on magnetic mesoporous silica nanoparticles: catalytic efficacy in one-pot synthesis of 5-substituted-1H-tetrazoles, antibacterial activity evaluation and immobilization of alpha-amylase. Applied Organometallic Chemistry; 34 (5) e5572.
  • 21. Tahmasbi, L, Sedaghat, T, Motamedi, H, Kooti, M. 2018. Mesoporous silica nanoparticles supported copper(II) and nickel(II) Schiff base complexes: Synthesis, characterization, antibacterial activity and enzyme immobilization. Journal of Solid State Chemistry; 258: 517-525.
  • 22. Ramu, VG, Bordoloi, A, Nagaiah, TC, Schuhmann, W, Muhler, M, Cabrele, C. 2012. Copper nanoparticles stabilized on nitrogen-doped carbon nanotubes as efficient and recyclable catalysts for alkyne/aldehyde/cyclic amine A(3)-type coupling reactions. Applied Catalysis A: General; 431: 88-94.
  • 23. Dayan, S, Kayaci, N, Dayan, O, Ozdemir, N, Ozpozan, NK. 2020. Nickel (II) complex [NiCl2(DMF)2L2] bearing diaminobenzene and sulfonamide: Crystal structure and catalytic application in the reduction of nitrobenzenes. Polyhedron; 175: 114181.
  • 24. Baghbamidi, SE, Hassankhani, A, Sanchooli, E, Sadeghzadeh, SM. 2018. The reduction of 4-nitrophenol and 2-nitroaniline by palladium catalyst based on a KCC-1/IL in aqueous solution. Applied Organometallic Chemistry; 32 (4): e4251.
  • 25. Kamal, T. 2019. Aminophenols formation from nitrophenols using agar biopolymer hydrogel supported CuO nanoparticles catalyst. Polymer Testing; 77: 105896.
  • 26. Mahmoud, ME, Amira, MF, Abouelanwar, ME, Seleim, SM. 2020. Catalytic reduction of nitrophenols by a novel assembled nanocatalyst based on zerovalent copper-nanopolyaniline-nanozirconium silicate. Journal of Molecular Liquids; 299: 112192.
  • 27. Li, ML, Chen, GF. 2013. Revisiting catalytic model reaction p-nitrophenol/NaBH4 using metallic nanoparticles coated on polymeric spheres, Nanoscale; 5 (23):11919-11927.
  • 28. Sun, HZ, Zelekew, OA, Chen, XY, Guo, YB, Kuo DH, Lu, QX, Lin, JG. 2019. A noble bimetal oxysulfide CuVOS catalyst for highly efficient catalytic reduction of 4-nitrophenol and organic dyes. RSC Advances; 9 (55): 31828-31839.
  • 29. Ahsan, MA, Jabbari, V, El-Gendy, AA, Curry, ML, Noveron, JC. 2019. Ultrafast catalytic reduction of environmental pollutants in water via MOF-derived magnetic Ni and Cu nanoparticles encapsulated in porous carbon. Applied Surface Science; 497: 143608.
  • 30. Liang, X, Chen, XW, Xiang, ZL, Yan, R, Xi, H, Bian, T, Zhang, JJ, Zhao, JX, Cai, QH, Wang, HX. 2018. Design and synthesis of surface-controlled CuOx/rGO nanocomposites with unusually high efficiency in catalytic conversion of organic reactants in the presence of NaBH4. Applied Surface Science; 459: 716-722.
Toplam 30 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Serkan Dayan 0000-0003-4171-7297

Yayımlanma Tarihi 29 Eylül 2020
Yayımlandığı Sayı Yıl 2020 Cilt: 16 Sayı: 3

Kaynak Göster

APA Dayan, S. (2020). Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes. Celal Bayar University Journal of Science, 16(3), 285-291. https://doi.org/10.18466/cbayarfbe.742711
AMA Dayan S. Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes. CBUJOS. Eylül 2020;16(3):285-291. doi:10.18466/cbayarfbe.742711
Chicago Dayan, Serkan. “Copper Nanoparticles Supported on a Schiff Base-Fullerene As Catalyst for Reduction of Nitrophenols and Organic Dyes”. Celal Bayar University Journal of Science 16, sy. 3 (Eylül 2020): 285-91. https://doi.org/10.18466/cbayarfbe.742711.
EndNote Dayan S (01 Eylül 2020) Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes. Celal Bayar University Journal of Science 16 3 285–291.
IEEE S. Dayan, “Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes”, CBUJOS, c. 16, sy. 3, ss. 285–291, 2020, doi: 10.18466/cbayarfbe.742711.
ISNAD Dayan, Serkan. “Copper Nanoparticles Supported on a Schiff Base-Fullerene As Catalyst for Reduction of Nitrophenols and Organic Dyes”. Celal Bayar University Journal of Science 16/3 (Eylül 2020), 285-291. https://doi.org/10.18466/cbayarfbe.742711.
JAMA Dayan S. Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes. CBUJOS. 2020;16:285–291.
MLA Dayan, Serkan. “Copper Nanoparticles Supported on a Schiff Base-Fullerene As Catalyst for Reduction of Nitrophenols and Organic Dyes”. Celal Bayar University Journal of Science, c. 16, sy. 3, 2020, ss. 285-91, doi:10.18466/cbayarfbe.742711.
Vancouver Dayan S. Copper Nanoparticles Supported on a Schiff base-Fullerene as Catalyst for Reduction of Nitrophenols and Organic Dyes. CBUJOS. 2020;16(3):285-91.