Nanoparticle – Based Materials for Various Applications

Authors

  • Z. Mansurov The Institute of Combustion Problems, 050012, Bogenbay batyr str. 172, Almaty, Kazakhstan

DOI:

https://doi.org/10.18321/ectj482

Keywords:

nanoparticle, aerogel, carbon nanotubes, 2D heterostructures, 3D printing

Abstract

The paper reviews recent scientific developments at the Institute of Combustion Problems. The hydrophobic sponges were obtained by coating polyurethane and melamine sponges with carbon nanomaterials. They are excellent water-resistant sorbents for oil, petroleum products and other organic liquids of various densities. Another interesting development is concerned to the synthesis of multiwalled carbon nanotubes on a glass-cloth by use of cobalt oxide catalyst nanoparticles obtained by solution combustion and production of the smart-textile on its basis. A model of soldier with heated jacket based on electroconductive smart-textile was made. The textile showed good electroconductive properties and effective Joule heating by externally applied current. Studies on the development of nanostructured carbon materials and their application as high-performance active components for the electrodes of advanced energy storage systems, in particular electric double layer capacitors were carried out. 2D heterostructures based on graphene and dichalcogenides of transition metals were derived. The epitaxial and single crystals of graphene were synthesized by the CVD-method separately on a copper foil. Two dimension WS2 layers were synthesized using sulfurization of thin WO3 films deposited by thermal evaporating on the FTO substrate. A setting time of concrete mass, which could be used as a construction material for 3D printing technology was determined. It was found that calcium chloride decreased the setting time up to 10 min, which is sufficient for the intended application.

References

[1]. Z.A. Mansurov, T.A. Shabanova, N.N. Mofa, Sintez i tehnologii nanostrukturirovannyh materialov [Synthesis and technologies nanostructured materials]: Textbook. – Almaty: Kazak University, 2012. – 318 P. (in Russian).

[2]. Z.A. Mansurov, Full scheme for fullerene, graphene, and soot formation in flame. Program Book: Carbon-2016. – Pennsylvania. USA. – P. 11.

[3]. K. Arivalagan, S. Ravichandran, K. Rangasamy and E. Karthikeyan, Int. J. Chem. Tech Res. 3 (2) (2011) 534–538.

[4]. Y. Hanzawa, K. Kaneko, R. Pekala, M. Dresselhaus, Langmuir 12 (1996) 6167–6169. <a href="https://doi.org/10.1021/la960481t">Crossref</a>

[5]. F.R. Sultanov, Shin-Shem Steven Pei, M. Auyelkhankyzy, B.T. Lesbayev, Z.A. Mansurov, Eurasian Chemico-Technological Journal 16 (4) (2014) 265–269. <a href="https://doi.org/10.18321/ectj9">Crossref</a>

[6]. Z. Mansurov, Fail Sultanov, Shin-Shem Pei, Su-Chi Chang, Sirui Xing, Francisco Robles- Hernandez, Yu-Wen Chi, Kun-Ping Huang. Microwave Plasma Enhanced CVD graphene-based aerogels: synthesis and study // Proceedings of conference "Сarbon 2015", Dresden, July 12-17, 2015, Germany, P. 2327.

[7]. G.T. Smagulova, S. Kim, N.G. Prikhod’ko, B.T. Lesbayev, A.V. Mironenko, A.A. Zakhidov,
Z.A. Mansurov, Int. J. Self-Propag. High-Temp Synth. 25 (3) (2016) 173‒176. <a href="https://doi.org/10.3103/S1061386216030122">Crossref</a>

[8]. G.T. Smagulova, N.B. Mansurov, N.G. Prikhodko, A.V. Mironenko, A.A. Zakhidov, Z.A. Mansurov, Synthesis of carbon nanotubes on catalysts prepared by solution combustion on glass-fibers // European Combustion Meeting, Budapest, Hungary. – 30 March-2 April. 2015. – P. 117–118.

[9]. Z.D. Kovalyuk, S.P. Yurtsenyuk, V.M. Bodyarashek, V.V. Netyaga, N.S. Yurtsenyuk, Electrochemical energy 10 (4) (2010) 208–213.

[10]. Z.A. Mansurov, V.V. Pavlenko, М.А. Bijsenbayev, А.P. Kurbatov, A.A. Zakhidov, N.G. Prikhodko, P. Cleszyk, F. Beguin, Gorenie i Plazmohimija [Combustion and Plasmochemistry] 2015, P. 176– 179 (in Russian).

[11]. V. Pavlenko, M. Biisenbaev, A. Zakhidov, F. Béguin, Z. Mansurov. Development of active carbons’ porous structure for their application in supercapacitors // Proceedings of conference "Сarbon 2015", Dresden, July 12-17, 2015, Germany.

[12]. V. Pavlenko, Q. Abbas, M. Biisenbaev, K. Fic, A. Zakhidov, F. Béguin, Z. Mansurov. Electrochemical performance in supercapasitors of carbon prepared from rice husk. Program Book: Carbon-2016. – Pennsylvania. USA. – P. 232.

[13]. R. Beisenov, Z.A. Mansurov, R. Ibrahim, D. Muratov, S.Zh. Tokmoldin and A. Ignatiev. Gorenie i Plazmohimija [Combustion and Plasmochemistry] 2015 – P. 76-78 (in Russian).

[14]. R. Beisenov, Z.A. Mansurov. Karbid kremnija: Osnovnye harakteristiki, metody poluchenija i primenenija [Silicon Carbide: Basic characteristics, methods of obtaining and application] // "Kazakh University". - 2015. – 150 p. // ISBN 978-601-04- 1182-1 (in Russian).

[15]. R. Beisenov, Z.A. Mansurov. Epitaxial growth of graphene and dichalcogenides of transition metal by CVD method // All-Russian school-conference with international participation. – Abstracts book. «Chemistry and physics of combustion and dispersed systems». – 2016. – P. 14–17.

[16]. B. Khoshnevis, Automat. Constrtion. 13 (1) (2004) 5–19. <a href="https://doi.org/10.1016/j.autcon.2003.08.012">Crossref</a>

[17]. Bethany C. Gross, Jayda L. Erkal, Sarah Y. Lockwood, Chengpeng Chen, and Dana M. Spence, Anal. Chem. 86 (2014) 3240−3253. <a href="https://doi.org/10.1021/ac403397r">Crossref</a>

[18]. Ch. Daulbayev, M. Rodin, Y. Aliyev, Z. Mansurov. Determination of certain additive that accelerates the setting time of concrete mass for 3D printing. Conference abstracts of 5th International conference ZEMCH 2016 (Zero Energy Mass Housing), Malaysia. P. 108-114.

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Published

2016-10-27

How to Cite

Mansurov, Z. (2016). Nanoparticle – Based Materials for Various Applications. Eurasian Chemico-Technological Journal, 18(4), 251–261. https://doi.org/10.18321/ectj482

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Section

Articles