New Method of Chemical Substances Conversion – Aerosol Nanocatalysis Technology. The way of Development

Iryna Glikina; Marat Glikin; Eugene Zubcov

doi:10.4028/p-kU9vVy

Paper Titles

Assessment of the Level of Greenery in Certain Districts of Odesa
p.81

Improving Methods for Assessing the Quality of Water Objects as Sources of Irrigation Water (on the Example of Rivers in the Odesa Region)
p.87

Preparation and Characteristics of Films Based on Polyvinyl Alcohol and Starch for Environmentally Friendly Packaging
p.101

Evaluation of the Impact of Wearing a Filtering Half Mask on the Cognitive Indicators of Users
p.109

New Method of Chemical Substances Conversion – Aerosol Nanocatalysis Technology. The way of Development
p.121

On Obtaining Nanomaterials from Industrial Waste
p.133

Environmentally Safe Increase in Productivity of Amaranth under the Action of Growth Stimulants
p.143

Problems of Waste Management in Wartime Conditions
p.151

Ecosystem Services of Natural Systems North-Western Shelf of the Black Sea: Current Status and Problems of Use
p.159

HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 162New Method of Chemical Substances Conversion –...

New Method of Chemical Substances Conversion – Aerosol Nanocatalysis Technology. The way of Development

Abstract:

The article provides information about the history of heterogeneous catalysis development. The new aerosol nanocatalysis technology is shown as perspective world nanotechnology. It took up to 20 years to fully understand the technology of aerosol nanocatalysis based on the experimental results obtained. This technology became known to the world from 1996 to the present. The article contains the history of the development of catalysis and technology of aerosol nanocatalysis. The results of research on aerosol nanocatalysis technology were monitored, taking into account its application in industry. Aerosol nanocatalysis technology has been proven successful for environmentally chemical transformations. Industrial and household waste disposal processes using this technology can be called waste-free. The article analyzes the main principles of aerosol nanocatalysis technology and traditional heterogeneous catalysis. The main technological parameters of aerosol nanocatalysis technology are considered. A study of chemical transformations using the technology of aerosol nanocatalysis in a fluidized and vibrating bed was carried out. A SWOT analysis was conducted comparing the technologies of traditional heterogeneous catalysis and aerosol nanocatalysis. Aerosol nanocatalysis technology is promising for the chemical, oil refining and other industries. The ecological condition of industrial and household waste processing technology is considered resource-saving. Aerosol nanocatalysis technology has no analogues in the world. The technological scheme of aerosol nanocatalysis technology is simple. It has been established that this scheme can be applied both for stationary and mobile installations. It has been found that aerosol nanocatalysis technology can transform chemical substances with any aggregate state.

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Periodical:

Advances in Science and Technology (Volume 162)

Pages:

121-132

DOI:

https://doi.org/10.4028/p-kU9vVy

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Online since:

April 2025

Authors:

Iryna Glikina*, Marat Glikin, Eugene Zubcov

Keywords:

Aerosol Nanocatalysis, Chemical Process, Ecologic, Industrial Waste Treatment, Nanotechnology

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* - Corresponding Author

References

[1] William H. Brock. The History of Chemistry. A Very Short Introduction. Oxford: Oxford University Press (2015). https://dokumen.pub/william-h-brock-the-history-of-chemistry-a-very-short-introduction-oup-oxford-2015.html

DOI: 10.1086/690795

Google Scholar

[2] Peters Baron. Reaction Rate. Theory and Rare Events, 1st edition, Elsevier Science, Oxford, 2017 https://inspectioncopy.elsevier.com/book/details/9780444563491

Google Scholar

[3] Giovanni Palmisano, Samar Al Jitan, Corrado Garlisi, Heterogeneous Catalysis, Elsevier, 2022

DOI: 10.1016/C2020-0-02936-1

Google Scholar

[4] Morris D. Argyle, Calvin H. Bartholomew, Heterogeneous Catalyst Deactivation and Regeneration. A Review. Catalysts, 5, 2015, pp.145-269

DOI: 10.3390/catal5010145

Google Scholar

[5] Yoshihisa Sakata, Yuki Tamauraa, Hayao Imamuraa, Masaya Watanabeb, Preparation of a New Type of CaSiO3 with High Surface Area and Property as a Catalyst Support, Studies in Surface Science and Catalysis, 162, 2006, pp.331-338

DOI: 10.1016/S0167-2991(06)80924-9

Google Scholar

[6] Graham J. Hutchingsa, Jacques C. Vedrine, Heterogeneous Catalyst Preparation. Basic Principles in Applied Catalysis, 75, 2004, pp.215-257

DOI: 10.1007/978-3-662-05981-4_6

Google Scholar

[7] М.А. Glikin, Aerozolnyj kataliz, Teoreticheskie osnovy ximicheskoj tekhnologii, Vol.30, N 4, 1996, p.430–435

Google Scholar

[8] Ivan Saldan, Oksana Dobrovetska, Oksana Makota, Nanotechnologies for Preparation and Application of Metallic Nickel, Chemistry and Chemical Technology, Vol.16, N 1, 2022, pp.74-94

DOI: 10.23939/chcht16.01.074

Google Scholar

[9] P.E. Strizhak, S.О. Soloviov, А.І. Trypolskyj, P.І. Kyrienko, І.L. Stolyarchuk, Avtonomnyj bezpolum'yanyj generator tepla na osnovi katalitychnogo okyslennya metanu abo propan-butanovoi sumishi dlya opalennya riznykh ob'ektiv, v tomu chysli v polyovykh umovah, Nauka innovation, Vol.12(5), 2016, pp.32-46

DOI: 10.15407/scin12.05.032

Google Scholar

[10] М.А. Glikin, I.М. Glikina, Heterogennyj gazofaznyj aerosolnyj nanokataliz, 1st edition, Harkiv, Pidruchnyk HPI (2015) 472

Google Scholar

[11] D.А. Frank-Kamenetskij, Dyffuziya i teploperedacha v himichnoj kinetyke, Nauka (1967) 502

Google Scholar

[12] Zohreh Zobeidi, Roohollah Sadeghi, Mohamad-Taghi Rostami, Effects of Brownian Motions and Fractal Structure of Nanoparticles on Natural Convection, Chemistry and Chemical Technology, Vol.17, N 3 (2023) p.617–624

DOI: 10.23939/chcht17.03.617

Google Scholar

[13] I. Glikina, New types of reactors for chemical transformations of organic compounds in terms of aerosol nanocatalysis technology, ТЕKA. Commission of motorization and energetics in agriculture, Vol.15, N 2 (2015) pp.69-74

Google Scholar