Vol. 12, no.3, 2020
РусскийEnglish
NANOSYSTEMS
ALUMINUM NANOSTRUCTURES OBTAINED AT THE INTERFACE OF TWO IMMISCIBLE LIQUID
Elmira T. Murzabekova, Saadat K. Sulaymankulova
Institute of Phytotechnology, National Academy of Sciences of Kyrgyz Republic, http://www.ihftnaskr.kg/
Bishkek 720071, Kyrgyzstan
E-mail: elmiramurzabek@mail.ru, sulaymankulova@mail.ru
Zhypargul D. Abdullaeva
Osh State University, http://medical.oshsu.kg/
Osh 723500, Kyrgyzstan
E-mail: jypar.science@oshsu.kg
Kutman K. Toktobaev
Company KAZ Minerals Bozymchak, https://www.kazminerals.com/bozymchak/
Bishkek, 720010, Kyrgyzstan
E-mail: toktobaev.kg@gmail.com
Zhazgul K. Kelgenbaeva
I.K. Akhunbaev Kyrgyz State Medical Academy, https://www.kgma.kg/
Bishkek 720020, Kyrgyzstan
E-mail: kelgenbaeva@mail.ru
Vitaly Yu. Mayorov
Institute of Chemistry, Far East branch of Russian Academy of Sciences, http://www.ich.dvo.ru/
Vladivostok 690022, Russian Federation
E-mail: 024250@inbox.ru
Received August 10, 2020; peer reviewed August 19, 2020; accepted August 31, 2020
Abstract. Expanding range of nanostructured materials applications based on aluminum initiates the search for new methods for their preparation. A promising method for the synthesis of aluminum nanostructures using the total energy of pulsed plasma and the energy of the interface is proposed in this article. Aluminum nanostructures have been synthesized by dispersing aluminum electrodes in a microemulsion (water-benzene), in benzene and distilled water, using the energy of a pulsed plasma. Obtained nanostructures of aluminum were subjected to X-ray phase and electron microscopic analyzes. Particle sizes are calculated using the Debye-Scherrer formula. The specific surface area (BET method) and porosity (BJH method) of nanostructures synthesized in microemulsion (water-benzene) were determined by the method of physical nitrogen adsorption.
Keywords: pulsed plasma in liquid, nanostructures, microemulsion, interfacial surface, specific surface area, pore volume
UDC 546.62
RENSIT, 2020, 12(3):369-378. DOI: 10.17725/rensit.2020.12.369.
Full-text electronic version of this article - web site http://en.rensit.ru/vypuski/article/348/12(3)369-378e.pdf