Formation of new intermetallic phases
in the Ta – Ni – Al system
A. S. Shchukin, D. Yu. Kovalev, A. E. Sytschev, A. V. Shcherbakov
Peculiarities of structure and phase formation in 5 Ta – 2 Ni – 3 Al intermetallic system were studied in the paper. The TaNiAl, NiAl, Ni2Al3 and Ta phases were found in the alloy produced by self-propagating high-temperature synthesis (SHS). A transition layer with the composition of Ta51Ni20Al29 about 1 – 2 µm thick was formed on the interface between an unreacted Ta particles and TaNiAl phase. Re-melting of the synthesized alloy at a temperature of about 3000°C leads to the formation of three structural components with the following compositions — Ta85Ni7Al8, Ta52Ni20Al28 and Ta53Ni25Al22. X-Ray analysis of the re-melted alloy showed the presence of reflections that do not correspond to any of the known phases in Ta-Ni-Al system. The alloy with a similar composition was synthesized by electro-thermal explosion (ETE) under load. Synthesized alloy has heterogeneous structure and multiphase composition of the surface layer which is similar to the alloy produced by SHS. Central sample region of the sample produced by ETE is similar to the structural and phase composition of the sample melted at temperature of 3000 °C. The obtained data show the possibility of synthesizing in Ta-Ni-Al system various phases with high Ta content (more than 50 at%).
Keywords: intermetallic, tantalum, Ta – Ni – Al, self-propagating high-temperature synthesis, SHS.
DOI: 10.30791/1028-978X-2019-10-5-13
Shchukin Alexandr — Merzhanov Institute of Structural Macrokinetics and Materials Science Russian Academy of Sciences (Chernogolovka, 142432, Academician Osipyan ul., 8), PhD (Eng), researcher, specialist in the microstructural research and self-propagating high-temperature synthesis. E-mail: shchukin@ism.ac.ru.
Kovalev Dmirty — Merzhanov Institute of Structural Macrokinetics and Materials Science Russian Academy of Sciences (Chernogolovka, 142432, Academician Osipyan ul., 8), PhD (Eng), head of laboratory, specialist in XRD analysis. Е-mail: kovalev@ism.ac.ru.
Sytschev Alexander — Merzhanov Institute of Structural Macrokinetics and Materials Science Russian Academy of Sciences (Chernogolovka, 142432, Academician Osipyan ul., 8), PhD (Eng), head of laboratory, specialist in the self-propagating high-temperature synthesis and materials science. Е-mail: sytschev@ism.ac.ru.
Shcherbakov Andrew — Merzhanov Institute of Structural Macrokinetics and Materials Science Russian Academy of Sciences (Chernogolovka, 142432, Academician Osipyan ul., 8), junior researcher, specialist in the self-propagating high-temperature synthesis of refractory materials. Е-mail: ismandrew@ism.ac.ru.
Reference citing
Shchukin A. S., Kovalev D. Yu., Sytschev A. E., Shcherbakov A. V. Poluchenie novyh intermetallidnyh faz v sisteme Ta – Ni – Al [Formation of new intermetallic phases in the Ta – Ni – Al system]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 5 – 13. DOI: 10.30791/1028-978X-2019-10-5-13
Particularities of estimating the optical band gap
of the phase change memory thin films
P. I. Lazarenko, Yu. V. Vorobyov, M. E. Fedyanina,
A. A. Sherchenkov, S. A. Kozyukhin,
A. O. Yakubov, A. V. Kukin, Yu. S. Sybina, I. V. Sagunova
The results of transmission and reflection spectra recording by spectrophotometry were used to study the peculiarities of estimating the optical band gap for Ge2Sb2Te5 thin films after annealing at different temperatures, in particular, in the phase transition temperature range. A significant influence of the spectrum processing algorithms on the obtained results was shown. A comparison of experimental data showed that the surface resistivity, reflection coefficient and optical band gap have different temperature ranges of variation during the crystallization process. In particular, changes of the electrophysical properties continue after the completion of the modification of optical characteristics, which indicates on the two-stage nature of the crystallization process in the Ge2Sb2Te5 films.
Keywords: phase change memory (PCM), chalcogenides, Ge2Sb2Te5 (GST225), thermal annealing, spectrophotometry, optical properties, Tauc method, optical band gap.
DOI: 10.30791/1028-978X-2019-10-14-25
Lazarenko Petr — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, Shokina, 1), Ph.D., associate professor, specialist in electronics and microelectronics. E-mail: lpi@org.miet.ru, aka.jum@gmail.com.
Vorobyov Yuri — Ryazan State Radio Engineering University (Ryazan, 390005, Gagarina ul, 59/1), PhD (Phys-Math), chief engineer, specialist in the field of solid-state electronics. E-mail: vorobjov.y.v@rsreu.ru.
Fedyanina Mariya — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, pl. Shokina, 1), bachelor, engineer, specialist in electronics and microelectronics. E-mail: mahamaha1996@gmail.com.
Sherchenkov Alexey — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, pl. Shokina, 1), Dr Sci (Eng), professor, specialist in physics and technology of semiconductors. E-mail: mfh.miet@gmail.com.
Kozyukhin Sergey — Kurnakov Institute of General and Inorganic Chemistry of the Russian Academy of Sciences (Moscow, 119991, Leninsky Pr., 31), Dr Sci (Chem), professor, expert in the field for physical chemistry of non-crystalline semiconductors. E-mail: sergkoz@igic.ras.ru.
Yakubov Alexey — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, pl. Shokina, 1) postgraduate, engineer, specialist of electronic and microelectronics. E-mail: alexsey007@mail.ru.
Kukin Alexey — The Hebrew University (The Edmond J. Safra Campus, Givat Ram Jerusalem 9190401) PhD, researcher, specialist in silicon photonics. E-mail:
aleksey.kukin@mail.huji.ac.il.
Sybina Yuliya — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, pl. Shokina, 1), graduate student, junior researcher, specialist in electronics and nanoelectronics. E-mail: nngrigor312@mail.ru.
Sagunova Irina — National Research University of Electronic Technology (Moscow, Zelenograd, 124498, pl. Shokina, 1), PhD, assistant professor, specialist in microelectronics and solid state electronics. E-mail: sagunova@list.ru.
Reference citing
Lazarenko P. I., Vorobyov Yu. V., Fedyanina M. E., Sherchenkov A. A., Kozyukhin S. A., Yakubov A. O., Kukin A. V., Sybina Yu. S., Sagunova I. V. Osobennosti opredeleniya opticheskoj shiriny zapreshchennoj zony tonkih plenok materialov fazovoj pamyati [Particularities of estimating the optical band gap of the phase change memory thin films]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 14 – 25. DOI: 10.30791/1028-978X-2019-10-14-25
Investigation of stainless steel, obtained by additive technology, applied to the operating conditions of liquid metal heat exchange systems
M. A. Ladyko, I. E. Lyublinski, A. G. Eremin, I. A. Logachev,
Zh. A. Sentyurina, P. S. Dzhumaev
Investigated properties of stainless steel grade GP1, obtained by additive technology (AT) by the method of selective laser melting (SLM) in relation to the operating conditions of liquid metal heat-exchange systems of power plants (vacuum density, corrosion effect of eutectic sodium and potassium alloy Na – K at temperature 700 ± 5 °С). The microstructure of GP1 steel has a fine structure with a characteristic size of structural components from 2 to 3 microns. The results of local chemical analysis of the identified structural components of the material showed a high degree of material homogeneity. The material is sealed, the flow of helium into the sample made by AT was no more than 4·10–10 (Pa·m3)/s. Under the conditions of the tests performed, the corrosive effect of Na – K on the material is observed in the surface layers with a thickness of no more than 2 microns. The corrosion rate of the test material under test conditions was less than 0,01 mm/year, which, according to the existing classification of corrosion resistance, makes it possible to assign the test material under test conditions to the resistance group — very persistent. The results give grounds to continue research on a larger time base and in conditions close to the operating conditions of the heat-exchange systems of power plants (non-isothermal dynamic conditions), as well as to conduct research on other steels obtained by AT, for example, chromium-nickel corrosion-resistant steel of austenitic class with a high level corrosion resistance in the environment of the liquid metal coolant Na – K of eutectic composition.
Key words: additive technology, selective laser melting, stainless steel, microstructure, vacuum impermeability, eutectic sodium and potassium alloy.
DOI: 10.30791/1028-978X-2019-10-26-34
Ladyko Maxim — “Red Star” JSC (Moscow, 115230, Elektrolitnyj proezd, 1A); Moscow Aviation Institute (National Research University) (Moscow, 125993, Volokolamskoe shosse, 4), researcher in “Red Star”, postgraduate, engineer in Moscow Aviation Institute, specialist in the development of nuclear power plants. E-mail: ladyko.maxim@yandex.ru.
Lyublinski Igor — “Red Star” (Moscow, 115230, Elektrolitnyj proezd, 1A), National Research Nuclear University “Moscow Engineering Physics Institute” (Moscow, 115409, Kashirskoye shosse, 31), PhD, head of department in “Red Star”, associate professor in Moscow Engineering Physics Institute, specialist in the field of engineering-physical and material science problems of thermonuclear and space energy. E-mail: lyublinski@yandex.ru.
Eremin Andrey — Moscow Aviation Institute (National Research University) (Moscow, 125993, Volokolamskoe shosse, 4), Dr Sci (Eng), professor, specialist in the development of nuclear power plants. E-mail: and.eremin0604@yandex.ru.
Logachev Ivan — Kompozit JSC (Korolev, 141070, Pionerskaya, 4), PhD, head of department, specialist in the field of heat-resistant materials and special electrometallurgy. E-mail: info@compozit-mv.ru.
Sentyurina Zhanna — Kompozit JSC (Korolev, 141070, Pionerskaya, 4), PhD, head of group, specialist in the field of powder metallurgy and composite materials. E-mail:
Sentyurina_misis@mail.ru.
Dzhumaev Pavel — National Research Nuclear University “Moscow Engineering Physics Institute” (Moscow, 115409, Kashirskoye shosse, 31), PhD, associate professor, specialist in the field of physical methods of materials research. E-mail: PSDzhumaev@mephi.ru.
Reference citing
Ladyko M. A., Lyublinski I. E., Eremin A. G., Logachev I. A., Sentyurina Zh. A., Dzhumaev P.S. Issledovanie svojstv korrozionnostojkoj stali, poluchennoj po additivnoj tekhnologii, primenitel'no k usloviyam ekspluatacii zhidkometallicheskih teploobmennyh sistem [Investigation of stainless steel, obtained by additive technology, applied to the operating conditions of liquid metal heat exchange systems]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 26 – 34. DOI: 10.30791/1028-978X-2019-10-26-34
The optimization of the synthesis conditions of ultra dispersed silver particles in the extract of hemp fiber
N. S. Dyimnikova, E. V. Erohina, A. P. Moryganov,
S. V. Grigorev, O. Yu. Kuznetsov
The impact of extraction conditions of natural admixtures (pectin compounds, hemicellulose and lignin) from hemp fiber has been evaluated in the process of chemical modification of fibrous mass. It was concluded, that for the maximum extraction admixtures the rise of temperature of fiber’s treatment up to 100 °С is required, and hydroxide natrium up to 10 g/l as well. It was proved by infrared spectroscopy and potentiometric titration methods that the raise of alkalinity boiling liquor leads to the rise of the number of admixtures in the liquor, to the destruction of admixtures as well. But the complex of reducing ingredients that has been formed in the liquor, plays a role as silver ion restorer even under conditions of low temperatures of extraction. The kinetics of silver ions restoration in extract liquor has been evaluated. The correlation of the effectivity of the restoration process of silver ions and number of admixtures in liquor was detected. The restoration in the liquor, that has been obtained under high alkalinity, leads to small sized particles formation (less 30 nm) that was proved by the photon correlation spectroscopy. It was proved that the antimicrobial activity against a test-cultures of the synthesized sols and cellulosic materials treated with the soles depends on the conditions of the synthesis.
Keywords: hemp fiber, extraction, natural admixtures, redox potential, synthesis, silver nanoparticles, antimicrobial activity.
DOI: 10.30791/1028-978X-2019-10-35-46
Dymnikova Natal’ja — G.A. Krestov Institute of Solution Chemistry of the Russian Academy of sciences, (Akademicheskaya st., 1, Ivanovo, 153045, Russia). PhD, researcher, specialist in the modification of textile materials. E-mail: nsd@isc-ras.ru.
Erohina Ekaterina — G.A. Krestov Institute of Solution Chemistry of the Russian Academy of sciences, (Akademicheskaya st., 1, Ivanovo, 153045, Russia), PhD (Chem), researcher, specialist in the modification of textile materials E-mail: erochina2007@yandex.ru.
Moryganov Andrej — G.A. Krestov Institute of Solution Chemistry of the Russian Academy of sciences, (Akademicheskaya st., 1, Ivanovo, 153045, Russia), Dr Sci (Eng), professor, head of the laboratory “Chemistry and technology of modified fibrous materials”. E-mail: apm@isc-ras.ru.
Grigoryev Sergey — N. I. Vavilov All-Russian Institute of Plant Genetic Resources
(42-44 b. Morskaya st., st. Petersburg, 190000, Russia), PhD (plant breeding), leading researcher, curator of hemp and bast crop genetic resources (mobilization, evaluation and prebreeding), cotton researcher. E-mail: ser.grig@mail.ru.
Kuznetsov Oleg — Ivanovo State Medical Academy of the Ministry of Healthcare of the Russian Federation (Ivanovo, Sheremetyevsky avenue, 8), Dr Sci (biol), professor, head of the department of microbiology and virology, a specialist in microbiology. E-mail: olegkuz58@ya.ru.
Reference citing
Dyimnikova N. S., Erohina E. V., Moryganov A. P., Grigorev S. V., Kuznetsov O. Yu. Optimizaciya uslovij sinteza ul'tradispersnyh chastic serebra v ekstrakte konoplyanogo volokna [The optimization of the synthesis conditions of ultra dispersed silver particles in the extract of hemp fiber]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 35 – 46. DOI: 10.30791/1028-978X-2019-10-35-46
Physical and mechanical properties of pyro-compacted
carbon-carbon material on a woven basis
G. E. Mostovoy, A. A. Konyushenkov
The work showed that a change in the length of the samples within 60 – 100 mm and a width within 12 – 25 mm, as well as the shape of the samples did not have a significant effect on the change in the mechanical characteristics when tested in compression in both directions of the UPA-4 material obtained by deposition pyrocarbon from the gas phase on the basis of graphite viscose fabric URAL-T-22. The carbon matrix of this material was formed as a result of the gradual deposition of pyrolytic carbon from the gas phase at a temperature of 980 °C for ~ 150 hours and at 1070 °C for ~ 100 hours. The paper presents the results of tests at different temperatures. Tests of flat specimens for bending, compressing, and stretching were performed at room temperature. To assess the heat resistance of the material, samples were tested for bending in a neutral argon medium at a speed of active capture 5 mm/min in a temperature range of 20 – 2800 °C. The tests have shown that the developed material is structural and heat-resistant, since in the temperature range up to 2200 °C it retains its bending strength, and as the temperature rises to
2500 °C, it deforms with plasticity without breaking.
Keywords: carbon-carbon composite materials, the pyrolytic carbon coating, carbon matrix, viscose, criteria t-test and the Fisher, dispersion, basis, filling, carbonization, graphitization, texturing, strengthening.
DOI: 10.30791/1028-978X-2019-10-47-53
Mostovoy Gennady — Test Center of Joint-stock company “Research Institute of structural materials based on graphite “Niigrafit” (111524, Moscow, Electrodnaya ul, 2), PhD (Eng), leading researcher, specialist in the field of mechanical testing and research of carbon and composite carbon-carbon materials at temperatures up to 3000 °C. E-mail: mostovoy.gennady@yandex.ru.
Konashenkov Andrey — Test Center of Joint-stock company “Research Institute of structural materials based on graphite “Niigrafit” (111524, Moscow, Electrodnaya ul, 2), Deputy chief of the Test Center, the specialist in the field of mechanical testing and studies of carbon and composite carbon-carbon materials at normal and low temperatures. E-mail: konju@yandex.ru.
Reference citing
Mostovoy G. E., Konyushenkov A. A. Fiziko-mekhanicheskie svojstva pirouplotnyonnogo uglerod-uglerodnogo materiala na tkanoj osnove [Physical and mechanical properties of pyro-compacted carbon-carbon material on a woven basis]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 47 – 53. DOI: 10.30791/1028-978X-2019-10-47-53
Surface physicochemical treatment of nickel foam
for increasing its electrocatalytic activity
in overall water splitting
D. V. Fominski, V. N. Nevolin, R. I. Romanov, V. Yu. Fominski,
O. V. Komleva, P. F. Kartsev, S. M. Novikov
The possibility of using physicochemical methods for treating nickel foam to increase its electrocatalytic activity in hydrogen and oxygen evolution reactions in an aqueous alkaline solution has been investigated. The modification of a 1 mm thick sheet of foam was carried out through its surface and included the physical deposition of a pulsed laser plasma for the formation of catalytic MoSx and MoSxSey films followed by their annealing. The effect of foam pretreatment by sulfurization in H2S under varying conditions, and the formation of catalytic layers with different structures and compositions was investigated. The greatest improvement of the electrocatalytic performance of the foam was exerted by thin-film coatings of molybdenum sulfide and sulfide/selenide with a nanocrystalline structure formed on the surface of a foam with a Ni3S2 underlayer. The possibility of the synergistic effect of the formed phases was analyzed by thermodynamic calculations in the frame of the density functional theory. For the optimal composition of the modified layers, the overvoltage of H2 evolution (for a current density of 10 mA/cm2) decreased to 155 mV, and the overvoltage of O2 evolution did not exceed 160 mV. The electrocatalytic characteristics obtained by this treatment are not inferior to those for the best modern electrocatalysts created on nickel foam by widely used methods of hydrothermal synthesis or electrodeposition.
Keywords: electrolysis, nickel foam, molybdenum sulfides, pulsed laser deposition, thermochemical treatment.
DOI: 10.30791/1028-978X-2019-10-54-66
Fominski Dmitriy — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), engineer of the department of solid state physics and nanosystems, specialist in the field of pulsed laser deposition of thin films and nanostructures. E-mail: dmitryfominski@gmail.com.
Nevolin Vladimir — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), Dr Sci (Phys-Math), professor of the department of solid state physics and nanosystems, specialist in the physics of thin films and nanostructures. E-mail: nevolin@sci.lebedev.ru.
Romanov Roman — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), PhD, researcher of the department of solid state physics and nanosystems, specialist in the field of physical and chemical methods for preparation and study of thin-film structures for various applications. E-mail: limpo2003@mail.ru.
Fominski Vyacheslav — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), Dr Sci (Phys-Math), professor, chief researcher of the department of solid state physics and nanosystems, specialist in the physics of thin films, nanostructures and beam surface modification technologies. E-mail: vyfominskij@mephi.ru.
Komleva Oxana — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), graduate student of the department of solid state physics and nanosystems, specialist in the field of production and study of MoS2-based catalysts. E-mail: deut2amu@gmail.ru.
Kartsev Petr — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), PhD, assistant professor of the department of solid state physics and nanosystems, specialist in the field of theoretical methods of solid state physics using quantum Monte Carlo methods and density functional theory. E-mail: PFKartsev@mephi.ru.
Novikov Sergey — National Research Nuclear University MEPhI (Moscow Engineering Physics Institute, Kashirskoe sh., 31, Moscow 115409, Russia), PhD, senior researcher of center for photonics and 2D materials, specialist in the Raman spectroscopy, surface-enhanced Raman spectroscopy (SERS), bio-nano-plasmonics. E-mail: Novikov.S@mipt.ru.
Reference citing
Fominski D. V., Nevolin V. N., Romanov R. I., Fominski V. Yu., Komleva O. V., Kartsev P. F., Novikov S. M. Poverhnostnaya fiziko-himicheskaya obrabotka nikelevoj peny dlya povysheniya ee elektrokataliticheskoj aktivnosti pri rasshcheplenii vody [Surface physicochemical treatment of nickel foam for increasing its electrocatalytic activity in overall water splitting]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 54 – 66. DOI: 10.30791/1028-978X-2019-10-54-66
Synthesis of hydro- and aerogels based on reduced graphene oxide, decorated by iron oxide nanoparticles, and research of their adsorption properties
E. A. Neskoromnaya, A. E. Burakov, A. V. Melezhik, A. V. Babkin,
I. V. Burakova, D. A. Kurnosov, A. G. Tkachev
Graphene is a promising material due to its unique chemical, physical, mechanical and thermal properties. The paper describes the synthesis method of a nanocomposite material based on graphene modified with nanoparticles of iron oxides, which is an effective sorbent of organic pollutants contained in aqueous media. Graphene production by chemical reduction of graphene oxide is the most flexible and popular method, which allows to obtain composite materials of various graphene-based structures. Chemical reduction of graphene oxide was performed using gamma-lactone 2,3-dehydro-L-gulonic acid (ascorbic acid). The method of obtaining the composite under investigation includes the treatment of the hydrogel obtained with supercritical isopropanol, which makes it possible to obtain a graphene aerogel containing nanoparticles of iron oxide (II, III). Analysis of the specific surface area and porosity showed an increase in the specific surface area of the aerogel by ~ 7 times as compared with a hydrogel dried under normal conditions in air. The diffractometric analysis of xerogel and aerogel samples suggests, that during supercritical drying in an organic fluid, the processes of reduction of iron hydroxide to iron oxide (II, III) proceed. The sorption capacity of hydro- and aerogel was studied using the example of extraction the molecules of the organic dye methylene blue from aqueous solutions in static mode (batch method). The results of the experiments showed that the maximum values sorption capacity for the methylene blue model dye were 1370 and 1326 mg/g for hydro- and aerogel, respectively.
Keywords: hydrogel, aerogel, supercritical processing, graphene oxide, iron oxides, ascorbic acid.
DOI: 10.30791/1028-978X-2019-10-67-79
Neskoromnaya Elena — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), graduate student, specialist in the field of adsorption technologies and carbon nanomaterials synthesis. E-mail: lenok.n1992@mail.ru.
Burakov Alexander — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), PhD, assistant professor of the specialist in the field of adsorption technologies and carbon nanomaterials synthesis. E-mail: m-alex1983@yandex.ru.
Melezhik Alexander — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), PhD (Chem), senior researcher. E-mail: nanocarbon@rambler.ru.
Babkin Alexander — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), graduate student, specialist in the field of adsorption technologies and carbon nanomaterials synthesis. E-mail: flex_trol@mail.ru.
Burakova Irina — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), PhD (Eng), assistant professor, specialist in the field of adsorption technologies and carbon nanomaterials synthesis. E-mail: iris_tamb68@mail.ru.
Kurnosov Dmitriy — Tambov State Technical University (Tambov, 392000, Leningradskaya, 1), master student, specialist in adsorption technologies and carbon nanomaterials synthesis. E-mail: ozikimoziki@mail.ru.
Reference citing
Neskoromnaya E. A., Burakov A. E., Melezhik A. V., Babkin A. V.,
Burakova I. V., Kurnosov D. A., Tkachev A. G. Sintez gidro- i aerogelej na osnove vosstanovlennogo oksida grafena, modificirovannogo nanochasticami oksidov zheleza, i issledovanie ih adsorbcionnyh svojstv [Synthesis of hydro- and aerogels based on reduced graphene oxide, decorated by iron oxide nanoparticles, and research of their adsorption properties]. Perspektivnye Materialy — Advanced Materials (in Russ), 2019, no. 10, p. 67 – 79. DOI: 10.30791/1028-978X-2019-10-67-79
