Research Article
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Year 2023, Volume: 10 Issue: 3, 577 - 588, 30.08.2023
https://doi.org/10.18596/jotcsa.1261839

Abstract

References

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  • 2. Bekyarova E, Fornasiero P, Kašpar J, Graziani M. CO oxidation on Pd/CeO2–ZrO2 catalysts. Catal Today [Internet]. 1998 Oct 19;45(1–4):179–83. Available from: <URL>.
  • 3. Bratan V, Munteanu C, Hornoiu C, Vasile A, Papa F, State R, et al. CO oxidation over Pd supported catalysts —In situ study of the electric and catalytic properties. Appl Catal B Environ [Internet]. 2017 Jun 15;207:166–73. Available from: <URL>.
  • 4. Carlsson P-A, Skoglundh M. Low-temperature oxidation of carbon monoxide and methane over alumina and ceria supported platinum catalysts. Appl Catal B Environ [Internet]. 2011 Jan 14;101(3–4):669–75. Available from: <URL>.
  • 5. Deng Y, Wang T, Zhu L, Jia A-P, Lu J-Q, Luo M-F. Enhanced performance of CO oxidation over Pt/CuCrOx catalyst in the presence of CO2 and H2O. Appl Surf Sci [Internet]. 2018 Jun 1;442:613–21. Available from: <URL>.
  • 6. Elazab HA, Moussa S, Brinkley KW, Gupton BF, El-Shall MS. The continuous synthesis of Pd supported on Fe3O4 nanoparticles: a highly effective and magnetic catalyst for CO oxidation. Green Process Synth [Internet]. 2017 Jan 28;6(4):413–24. Available from: <URL>.
  • 7. Mandapaka R, Madras G. Aluminium and rhodium co-doped ceria for water gas shift reaction and CO oxidation. Mol Catal [Internet]. 2018 May 1;451:4–12. Available from: <URL>.
  • 8. Zou Z-Q, Meng M, Zha Y-Q. Surfactant-Assisted Synthesis, Characterizations, and Catalytic Oxidation Mechanisms of the Mesoporous MnOx−CeO2 and Pd/MnOx−CeO2 Catalysts Used for CO and C3H8 Oxidation. J Phys Chem C [Internet]. 2010 Jan 14;114(1):468–77. Available from: <URL>.
  • 9. Arenz M, Mayrhofer KJJ, Stamenkovic V, Blizanac BB, Tomoyuki T, Ross PN, et al. The Effect of the Particle Size on the Kinetics of CO Electrooxidation on High Surface Area Pt Catalysts. J Am Chem Soc [Internet]. 2005 May 1;127(18):6819–29. Available from: <URL>.
  • 10. Du M, Sun D, Yang H, Huang J, Jing X, Odoom-Wubah T, et al. Influence of Au Particle Size on Au/TiO2 Catalysts for CO Oxidation. J Phys Chem C [Internet]. 2014 Aug 21;118(33):19150–7. Available from: <URL>.
  • 11. Joo SH, Park JY, Renzas JR, Butcher DR, Huang W, Somorjai GA. Size Effect of Ruthenium Nanoparticles in Catalytic Carbon Monoxide Oxidation. Nano Lett [Internet]. 2010 Jul 14;10(7):2709–13. Available from: <URL>.
  • 12. Raphulu M, McPherson J, Pattrick G, Ntho T, Mokoena L, Moma J, et al. CO oxidation: Deactivation of Au/TiO2 catalysts during storage. Gold Bull [Internet]. 2009 Dec;42(4):328–36. Available from: <URL>.
  • 13. Tana, Wang F, Li H, Shen W. Influence of Au particle size on Au/CeO2 catalysts for CO oxidation. Catal Today [Internet]. 2011 Oct 25;175(1):541–5. Available from: <URL>.
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  • 21. Dasireddy VDBC, Valand J, Likozar B. PROX reaction of CO in H2/H2O/CO2 Water–Gas Shift (WGS) feedstocks over Cu–Mn/Al2O3 and Cu–Ni/Al2O3 catalysts for fuel cell applications. Renew Energy [Internet]. 2018 Feb 1;116:75–87. Available from: <URL>.
  • 22. Dasireddy VDBC, Bharuth-Ram K, Hanzel D, Likozar B. Heterogeneous Cu–Fe oxide catalysts for preferential CO oxidation (PROX) in H2 -rich process streams. RSC Adv [Internet]. 2020 Sep 28;10(59):35792–802. Available from: <URL>.
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  • 26. Azimova GR. Study of low-temperature oxidation of carbon monooxide on Cu-Mn-Fe catalytic oxide systems obtained by the sol-gel combustion method. Azerbaijan Chem J [Internet]. 2022 Jun 22;2:93–9. Available from: <URL>.
  • 27. Zulfugarova SM, Ramiz AG, Fikret AZ, Humbat IE, Nikolayevich LY, Babir TD. Microwave Sol-gel Synthesis of Co, Ni, Cu, Mn Ferrites and the Investigation of Their Activity in the Oxidation Reaction of Carbon Monoxide. Curr Microw Chem [Internet]. 2022 Apr 4;9(1):37–46. Available from: <URL>.
  • 28. Njagi EC, Chen C-H, Genuino H, Galindo H, Huang H, Suib SL. Total oxidation of CO at ambient temperature using copper manganese oxide catalysts prepared by a redox method. Appl Catal B Environ [Internet]. 2010 Aug;99(1–2):103–10. Available from: <URL>.
  • 29. Jones C, Cole KJ, Taylor SH, Crudace MJ, Hutchings GJ. Copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation: Effect of calcination on activity. J Mol Catal A Chem [Internet]. 2009 Jun 15;305(1–2):121–4. Available from: <URL>.
  • 30. Dey S, Dhal GC. Catalytic conversion of carbon monoxide into carbon dioxide over spinel catalysts: An overview. Mater Sci Energy Technol [Internet]. 2019 Dec 1;2(3):575–88. Available from: <URL>.
  • 31. Aniz CU, Radhakrishnan Nair TD. A Study on Catalysis by Ferrospinels for Preventing Atmospheric Pollution from Carbon Monoxide. Open J Phys Chem [Internet]. 2011;1(3):124–30. Available from: <URL>.
  • 32. Prasad R, Singh P. A Review on CO Oxidation Over Copper Chromite Catalyst. Catal Rev [Internet]. 2012 Apr 1;54(2):224–79. Available from: <URL>.
  • 33. Bhagwat VR, Humbe A V., More SD, Jadhav KM. Sol-gel auto combustion synthesis and characterizations of cobalt ferrite nanoparticles: Different fuels approach. Mater Sci Eng B [Internet]. 2019 Sep 1;248:114388. Available from: <URL>.
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Cobalt-Containing Oxide Catalysts Obtained by The Sol-Gel Method with Auto-Combustion in The Reaction of Low-Temperature Oxidation of Carbon Monoxide

Year 2023, Volume: 10 Issue: 3, 577 - 588, 30.08.2023
https://doi.org/10.18596/jotcsa.1261839

Abstract

The reaction of low-temperature oxidation of carbon monoxide is important in the context of air purification and reduction of automotive emissions. Along with the search for active catalytic systems for carbon monoxide oxidation, the development of new energy-saving methods of catalyst synthesis also seems important. Cobalt-iron, cobalt-manganese, cobalt-chromium, cobalt-copper binary and cobalt-manganese-iron, cobalt-copper-iron-containing triple oxide systems for low-temperature oxidation of carbon monoxide into carbon dioxide were synthesized by the sol-gel method with auto-combustion. The samples were analyzed by X-ray diffraction, IR spectral and derivatographic methods of analysis, their specific surface area was measured by the BET method, micro-photographs were taken on a scanning electron microscope. It was established that the resulting binary and ternary cobalt-containing oxide systems are multiphase systems containing ferrites, manganites, and oxides of cobalt, copper, manganese, and iron. The resulting catalysts are active in the low-temperature oxidation of carbon monoxide at 145-180 °C. The activation energy of the CO oxidation reaction on the analyzed oxide systems was revealed by the Arrhenius equation is placed in the range of 17-33 kJ/mol. In the systems, an intensifying effect of the influence of its components on the catalytic activity is observed in the oxide and spinel phases. The Co-Cr=2:1 system, which, along with chromite, also contains cobalt oxide, which is active at a much lower temperature – 145 °C than systems with a Co-Cr=1:1 and 1:2 ratios. A similar dependence was obtained in the Co-Fe=2:1 system, i.e. in a sample that, along with cobalt ferrite, also contains cobalt oxide. On this catalyst, 100% conversion of CO to CO2 occurs at a temperature of 200 °C, and a Co-Fe = 1:2 sample with a stoichiometric ratio of metals, in which the ferritization reaction completely occurs, as experiments have shown, is active only at temperatures above 300 °C. The intensifying effect of the influence of the components on its activity is also observed in three-component systems, in which the complete conversion of CO occurs at a temperature of 145-160 °C. The appearance of various structural defects during short-term combustion of the gel without additional heat treatment, which can potentially be considered as catalytically active centers, on the one hand, and the presence of oxide and spinel phases in the composition of catalysts, which exhibit a mutual reinforcing effect, on the other hand, is demonstrative advantage of this method for the synthesis of active catalysts for low-temperature oxidation of carbon monoxide to dioxide.

References

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  • 2. Bekyarova E, Fornasiero P, Kašpar J, Graziani M. CO oxidation on Pd/CeO2–ZrO2 catalysts. Catal Today [Internet]. 1998 Oct 19;45(1–4):179–83. Available from: <URL>.
  • 3. Bratan V, Munteanu C, Hornoiu C, Vasile A, Papa F, State R, et al. CO oxidation over Pd supported catalysts —In situ study of the electric and catalytic properties. Appl Catal B Environ [Internet]. 2017 Jun 15;207:166–73. Available from: <URL>.
  • 4. Carlsson P-A, Skoglundh M. Low-temperature oxidation of carbon monoxide and methane over alumina and ceria supported platinum catalysts. Appl Catal B Environ [Internet]. 2011 Jan 14;101(3–4):669–75. Available from: <URL>.
  • 5. Deng Y, Wang T, Zhu L, Jia A-P, Lu J-Q, Luo M-F. Enhanced performance of CO oxidation over Pt/CuCrOx catalyst in the presence of CO2 and H2O. Appl Surf Sci [Internet]. 2018 Jun 1;442:613–21. Available from: <URL>.
  • 6. Elazab HA, Moussa S, Brinkley KW, Gupton BF, El-Shall MS. The continuous synthesis of Pd supported on Fe3O4 nanoparticles: a highly effective and magnetic catalyst for CO oxidation. Green Process Synth [Internet]. 2017 Jan 28;6(4):413–24. Available from: <URL>.
  • 7. Mandapaka R, Madras G. Aluminium and rhodium co-doped ceria for water gas shift reaction and CO oxidation. Mol Catal [Internet]. 2018 May 1;451:4–12. Available from: <URL>.
  • 8. Zou Z-Q, Meng M, Zha Y-Q. Surfactant-Assisted Synthesis, Characterizations, and Catalytic Oxidation Mechanisms of the Mesoporous MnOx−CeO2 and Pd/MnOx−CeO2 Catalysts Used for CO and C3H8 Oxidation. J Phys Chem C [Internet]. 2010 Jan 14;114(1):468–77. Available from: <URL>.
  • 9. Arenz M, Mayrhofer KJJ, Stamenkovic V, Blizanac BB, Tomoyuki T, Ross PN, et al. The Effect of the Particle Size on the Kinetics of CO Electrooxidation on High Surface Area Pt Catalysts. J Am Chem Soc [Internet]. 2005 May 1;127(18):6819–29. Available from: <URL>.
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  • 11. Joo SH, Park JY, Renzas JR, Butcher DR, Huang W, Somorjai GA. Size Effect of Ruthenium Nanoparticles in Catalytic Carbon Monoxide Oxidation. Nano Lett [Internet]. 2010 Jul 14;10(7):2709–13. Available from: <URL>.
  • 12. Raphulu M, McPherson J, Pattrick G, Ntho T, Mokoena L, Moma J, et al. CO oxidation: Deactivation of Au/TiO2 catalysts during storage. Gold Bull [Internet]. 2009 Dec;42(4):328–36. Available from: <URL>.
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  • 14. Royer S, Duprez D. Catalytic Oxidation of Carbon Monoxide over Transition Metal Oxides. ChemCatChem [Internet]. 2011 Jan 10;3(1):24–65. Available from: <URL>.
  • 15. Xanthopouloua GG, Novikova VA, Knysha YA, Amosova AP. Nanocatalysts for Low-Temperature Oxidation of CO: Review. Eurasian Chem J [Internet]. 2014 Dec 19;17(1):17–32. Available from: <URL>.
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  • 21. Dasireddy VDBC, Valand J, Likozar B. PROX reaction of CO in H2/H2O/CO2 Water–Gas Shift (WGS) feedstocks over Cu–Mn/Al2O3 and Cu–Ni/Al2O3 catalysts for fuel cell applications. Renew Energy [Internet]. 2018 Feb 1;116:75–87. Available from: <URL>.
  • 22. Dasireddy VDBC, Bharuth-Ram K, Hanzel D, Likozar B. Heterogeneous Cu–Fe oxide catalysts for preferential CO oxidation (PROX) in H2 -rich process streams. RSC Adv [Internet]. 2020 Sep 28;10(59):35792–802. Available from: <URL>.
  • 23. Al Soubaihi RM, Saoud KM, Dutta J. Critical Review of Low-Temperature CO Oxidation and Hysteresis Phenomenon on Heterogeneous Catalysts. Catalysts [Internet]. 2018 Dec 14;8(12):660. Available from: <URL>.
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  • 25. Zulfugarova SM, Azimova GR, Aleskerova ZF, Qasimov RJ, Bayramov MA, Ismailov EH, et al. Effect of preparation method of iron-, copper-containing oxide catalysts on their activity in the reaction of oxidation of carbon monoxide to carbon dioxide. Chem Probl [Internet]. 2022;20(1):82–94. Available from: <URL>.
  • 26. Azimova GR. Study of low-temperature oxidation of carbon monooxide on Cu-Mn-Fe catalytic oxide systems obtained by the sol-gel combustion method. Azerbaijan Chem J [Internet]. 2022 Jun 22;2:93–9. Available from: <URL>.
  • 27. Zulfugarova SM, Ramiz AG, Fikret AZ, Humbat IE, Nikolayevich LY, Babir TD. Microwave Sol-gel Synthesis of Co, Ni, Cu, Mn Ferrites and the Investigation of Their Activity in the Oxidation Reaction of Carbon Monoxide. Curr Microw Chem [Internet]. 2022 Apr 4;9(1):37–46. Available from: <URL>.
  • 28. Njagi EC, Chen C-H, Genuino H, Galindo H, Huang H, Suib SL. Total oxidation of CO at ambient temperature using copper manganese oxide catalysts prepared by a redox method. Appl Catal B Environ [Internet]. 2010 Aug;99(1–2):103–10. Available from: <URL>.
  • 29. Jones C, Cole KJ, Taylor SH, Crudace MJ, Hutchings GJ. Copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation: Effect of calcination on activity. J Mol Catal A Chem [Internet]. 2009 Jun 15;305(1–2):121–4. Available from: <URL>.
  • 30. Dey S, Dhal GC. Catalytic conversion of carbon monoxide into carbon dioxide over spinel catalysts: An overview. Mater Sci Energy Technol [Internet]. 2019 Dec 1;2(3):575–88. Available from: <URL>.
  • 31. Aniz CU, Radhakrishnan Nair TD. A Study on Catalysis by Ferrospinels for Preventing Atmospheric Pollution from Carbon Monoxide. Open J Phys Chem [Internet]. 2011;1(3):124–30. Available from: <URL>.
  • 32. Prasad R, Singh P. A Review on CO Oxidation Over Copper Chromite Catalyst. Catal Rev [Internet]. 2012 Apr 1;54(2):224–79. Available from: <URL>.
  • 33. Bhagwat VR, Humbe A V., More SD, Jadhav KM. Sol-gel auto combustion synthesis and characterizations of cobalt ferrite nanoparticles: Different fuels approach. Mater Sci Eng B [Internet]. 2019 Sep 1;248:114388. Available from: <URL>.
  • 34. Kaufmann Junior CG, Zampiva RYS, Alves AK, Bergmann CP, Giorgini L. Synthesis of cobalt ferrite (CoFe2O4) by combustion with different concentrations of glycine. IOP Conf Ser Mater Sci Eng [Internet]. 2019 Oct 1;659(1):012079. Available from: <URL>.
  • 35. Amini M, Kafshdouzsani MH, Akbari A, Gautam S, Shim C-H, Chae KH. Spinel copper ferrite nanoparticles: Preparation, characterization and catalytic activity. Appl Organomet Chem [Internet]. 2018 Sep 1;32(9):e4470. Available from: <URL>.
  • 36. Azimova GR, Zulfugarova SM, Aleskerova ZF, Ismailov EH. Catalytic activity of copper ferrite synthesized with the using of microwave treatment in the oxidation reaction of carbon monoxide. AJCN. 2020;2(2):29–35.
  • 37. Tang Z-R, Kondrat SA, Dickinson C, Bartley JK, Carley AF, Taylor SH, et al. Synthesis of high surface area CuMn2O4 by supercritical anti-solvent precipitation for the oxidation of CO at ambient temperature. Catal Sci Technol [Internet]. 2011 Jul 18;1(5):740–6. Available from: <URL>.
  • 38. Sun R, Zhang S, An K, Song P, Liu Y. Cu1.5Mn1.5O4 spinel type composite oxide modified with CuO for synergistic catalysis of CO oxidation. J Fuel Chem Technol [Internet]. 2021 Jun 1;49(6):799–808. Available from: <URL>.
  • 39. Grillo F, Natile MM, Glisenti A. Low temperature oxidation of carbon monoxide: the influence of water and oxygen on the reactivity of a Co3O4 powder surface. Appl Catal B Environ [Internet]. 2004 Apr 8;48(4):267–74. Available from: <URL>.
  • 40. Han SW, Kim DH, Jeong M-G, Park KJ, Kim YD. CO oxidation catalyzed by NiO supported on mesoporous Al2O3 at room temperature. Chem Eng J [Internet]. 2016 Jan 1;283:992–8. Available from: <URL>.
  • 41. Xie X, Li Y, Liu Z-Q, Haruta M, Shen W. Low-temperature oxidation of CO catalysed by Co3O4 nanorods. Nature [Internet]. 2009 Apr 9;458:746–9. Available from: <URL>.
  • 42. Singh SA, Madras G. Detailed mechanism and kinetic study of CO oxidation on cobalt oxide surfaces. Appl Catal A Gen [Internet]. 2015 Sep 5;504:463–75. Available from: <URL>.
  • 43. Gómez LE, Tiscornia IS, Boix A V., Miró EE. Co/ZrO2 catalysts coated on cordierite monoliths for CO preferential oxidation. Appl Catal A Gen [Internet]. 2011 Jul 15;401(1–2):124–33. Available from: <URL>.
  • 44. Alvarez A, Ivanova S, Centeno MA, Odriozola JA. Sub-ambient CO oxidation over mesoporous Co3O4: Effect of morphology on its reduction behavior and catalytic performance. Appl Catal A Gen [Internet]. 2012 Jul 26;431–432:9–17. Available from: <URL>.
  • 45. Jansson J. Low-Temperature CO Oxidation over Co3O4/Al2O3. J Catal [Internet]. 2000 Aug 15;194(1):55–60. Available from: <URL>.
  • 46. Lima TM, Castelblanco WN, Rodrigues AD, Roncolatto RE, Martins L, Urquieta-González EA. CO oxidation over Co-catalysts supported on silica-titania – The effects of the catalyst preparation method and the amount of incorporated Ti on the formation of more active Co3+ species. Appl Catal A Gen [Internet]. 2018 Sep 5;565:152–62. Available from: <URL>.
  • 47. Lou Y, Wang L, Zhao Z, Zhang Y, Zhang Z, Lu G, et al. Low-temperature CO oxidation over Co3O4-based catalysts: Significant promoting effect of Bi2O3 on Co3O4 catalyst. Appl Catal B Environ [Internet]. 2014 Mar 1;146:43–9. Available from: <URL>.
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There are 55 citations in total.

Details

Primary Language English
Subjects Chemical Engineering, Chemical Engineering (Other)
Journal Section RESEARCH ARTICLES
Authors

Sima Zulfugarova 0000-0001-9593-0099

Gunel R Azimova This is me 0000-0002-8501-2187

S Z Aleskerova This is me

Dilgam Tagiyev This is me 0000-0002-8312-2980

Publication Date August 30, 2023
Submission Date March 8, 2023
Acceptance Date May 10, 2023
Published in Issue Year 2023 Volume: 10 Issue: 3

Cite

Vancouver Zulfugarova S, Azimova GR, Aleskerova SZ, Tagiyev D. Cobalt-Containing Oxide Catalysts Obtained by The Sol-Gel Method with Auto-Combustion in The Reaction of Low-Temperature Oxidation of Carbon Monoxide. JOTCSA. 2023;10(3):577-88.