Innovations, Mechanisms, and Applications in Catalysis and Reaction Engineering
Abstract
Catalysis and Reaction Engineering are pivotal in the development of sustainable chemical processes, playing a crucial role in the efficient transformation of raw materials into valuable products. Recent advancements in this field have been driven by the need for greener processes, improved catalyst performance, and more effective reaction engineering methodologies. This review highlights the significant developments in catalysis and reaction engineering, focusing on novel catalytic materials, innovative reactor designs, and their applications in various industrial processes.
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reviews. 1997 Oct 1;97(6):2373-420.
2. Sinfelt JH. Role of surface science in catalysis. Surface Science. 2002 Mar 10;500(1-3):923-46.
3. Huber GW, Iborra S, Corma A. Synthesis of transportation fuels from biomass: chemistry,
catalysts, and engineering. Chemical reviews. 2006 Sep 13;106(9):4044-98.
4. Wang Y, Arandiyan H, Scott J, Bagheri A, Dai H, Amal R. Recent advances in ordered meso/macroporous metal
oxides for heterogeneous catalysis: a review. Journal of Materials Chemistry A. 2017;5(19):8825-46.
5. Chorkendorff I, Niemantsverdriet JW. Concepts of modern catalysis and kinetics. John Wiley & Sons;
2017 May 30.
6. Sheldon RA, Arends I, Hanefeld U. Green chemistry and catalysis. John Wiley & Sons; 2007 Jun 27.
7. Bell AT. The impact of nanoscience on heterogeneous catalysis. Science. 2003 Mar 14;299(5613):1688-91.
8. Balzani V. Nanoscience and nanotechnology: a personal view of a chemist. small. 2005 Mar 1;1(3):278-83
9. Nørskov JK, Abild-Pedersen F, Studt F, Bligaard T. Density functional theory in surface chemistry and
catalysis. Proceedings of the National Academy of Sciences. 2011 Jan 18;108(3):937-43.
10. Greeley J. Theoretical heterogeneous catalysis: scaling relationships and computational catalyst design. Annual review of chemical and biomolecular engineering. 2016 Jun 7;7:605-35.
11. Huber GW, Corma A. Synergies between bio‐and oil refineries for the production of fuels from biomass.
Angewandte Chemie International Edition. 2007 Sep 24;46(38):7184-201.
12. Palkovits R, Antonietti M, Kuhn P, Thomas A, Schüth F. Solid catalysts for the selective low‐temperature
oxidation of methane to methanol. Angewandte Chemie International Edition. 2009 Sep 1;48(37):6909-12.
13. Davis SE, Ide MS, Davis RJ. Selective oxidation of alcohols and aldehydes over supported metal nanoparticles.
Green Chemistry. 2013;15(1):17-45.
14. Xiang Q, Yu J. Graphene-based photocatalysts for hydrogen generation. The Journal of Physical Chemistry
Letters. 2013 Mar 7;4(5):753-9.
15. Zuo F, Wang L, Wu T, Zhang Z, Borchardt D, Feng P. Self-doped Ti3+ enhanced photocatalyst for hydrogen
production under visible light. Journal of the American Chemical Society. 2010 Sep 1;132(34):11856-7.
16. Thomas JM, Raja R, Lewis DW. Single‐site heterogeneous catalysts. Angewandte Chemie International Edition.
2005 Oct 14;44(40):6456-82
Published
2024-06-25
How to Cite
UPADHYAY, Girish.
Innovations, Mechanisms, and Applications in Catalysis and Reaction Engineering.
Journal of Advanced Research in Applied Chemistry and Chemical Engineering, [S.l.], v. 7, n. 1, p. 6-11, june 2024.
Available at: <http://thejournalshouse.com/index.php/Journal-Chemistry-ChemEng/article/view/1273>. Date accessed: 19 apr. 2025.
Section
Review Artcile
