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[1] | Мanaf R. Мanafov, Institute of Catalysis and Inorganic Chemistry named after Academician M. Nagiyev, National Academy of Sciences, Azerbaijan, Baku. |
[2] | Jeyran T. Rustamova, Institute of Catalysis and Inorganic Chemistry named after Academician M. Nagiyev, National Academy of Sciences, Azerbaijan, Baku. |
[3] | Goshgar S. Аliyev, Institute of Catalysis and Inorganic Chemistry named after Academician M. Nagiyev, National Academy of Sciences, Azerbaijan, Baku. |
[4] | Irada G. Melikova, Institute of Catalysis and Inorganic Chemistry named after Academician M. Nagiyev, National Academy of Sciences, Azerbaijan, Baku. |
[5] | Adile M. Aliyeva, Institute of Catalysis and Inorganic Chemistry named after Academician M. Nagiyev, National Academy of Sciences, Azerbaijan, Baku. |
Catalytic properties of natural zeolites in Cu-, Ni-, Co- and Mn ion-exchange forms have been studied in reaction of oxidative dehydrogenation of methanol. It was established that processes of dehydration as well as partial oxidation are going in all samples of catalysts. It has been identified a number of catalysts activity in the process of oxidative dehydrogenation of methanol: clCoX
Zeolite, Clinoptilolite, Catalyst, Methanol, Dehydrogenation
Kiselev V. F.,Krylov O.V. (1981)Adsorption and catalysis on transition metals and their oxides. M.: Chemistry, 286 p.
Rabo J. (1980)/ Ed. Chemistry of Zeolites and Catalysis on zeolites. Moscow: Mir, Vol.1. 506 p . V.2. 422 p.
Fenelonov V.B., Parmon V.N. (2006) Adsorption methods for measuring total and partial surface of heterogeneous catalysts and supports (the current state and development trends) // Industrial Catalysis lectures. Sat .: M . Kalvis, V.3. pp.77–119
Rustamova J.T., Alieva A.M., Efendi A.J., Melikova I.G., Nasiri F.M., Kozharova L.I., Shikhlinskaya T.A. (2014) A study of the catalytic properties of natural zeolites of Azerbaijan. // Austrian Journal of Technical and Natural Sciences. N5-6. Vienna. pp. 81–84. ISSN 2310-5607.
Bagirzade G.A., Tagiyev D.B., Manafov M.R. (2015) Vapor Phase Ammoxidation of 4-Phenyl-o-Xylene into 4-Phenylphthalonitrile on V-Sb-Bi-Zr/-Al2O3 Oxide Catalyst, Modern Research in Catalysis, V. 4, No.3, pp. 59–67.
Bagirzade G. A., Tagiyev D.B., Manafov M.R. (2014) Synthesis of 4-Phenylphthalonitrile by Vapor-Phase Catalytic Ammoxidation of Intermediate 4-Phenyl-o-Tolunitrile: Reaction Kinetics, Modern Research in Catalysis, V.3, No.1, pp. 6–11.
Fakhriyya M. Nasiri, Fikret A. Kuliev, Arif J. Efendy, Lyudmila I. Kojarova, Farida A. Abdullayeva, Irada H. Melikova, Natevan F. Aykan (2015) The Study of Inhibition Effect of Rhenium Thioacetic and Dithiocarbonic Acids in Oxidation Reaction, Advances in Chemical Engineering and Science (ACES), V.5, No.3, pp. 338–344.
Мanafov M.R., Mammadov E.M., Aliyev G.S. (2015) Application of Software Package “OptimMe” for the Study of the Process of Partial Oxidation of Propane , American Journal of Chemistry and Application, V.2 , No. 4, pp. 47–51.
Christopher Anastasi and Ian W. M. Smith. (1978) Rate measurements of reactions of OH by resonance absorption. Part 6.—Rate constants for OH + NO(+ M)→ HNO2(+ M) over a wide range of temperature and pressure. J. Chem. Soc., Faraday Trans. 2, 74, 1056-1064. DOI: 10.1039/F29787401056.
Shengkai Wang, Enoch E. Dames, David F. Davidson, and Ronald K. Hanson. (2014) Reaction Rate Constant of CH2O + H = HCO + H2 Revisited: A Combined Study of Direct Shock Tube Measurement and Transition State Theory Calculation. J. Phys. Chem. A, 118 (44), pp 10201–10209.DOI: 10.1021/jp5085795.
Amber Jain and Joseph E. Subotnik. (2015) Surface hopping, transition state theory, and decoherence. II. Thermal rate constants and detailed balance J. Chem. Phys. 143, 134107 http://dx.doi.org/10.1063/1.4930549.
P. N. Kalinkin, O. N. Kovalenko , V. M. Khanaev (2015) Direct oxidation of hydrogen sulfide over vanadium catalysts: I. Kinetics of the reaction Kinetics and Catalysis . V 56, Issue 1, pp. 106-114.
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Reference
[01]
[02]
[03]
[04]
[05]
[06]
[07]
[08]
[09]
[10]
[11]
[12]