正交微波合成，用镍完成。

Kondensirovannye sredy i mezhfaznye granitsy = Condensed Matter and Interphases Pub Date : 2019-06-15 DOI:10.17308/KCMF.2019.21/768

E. V. Tomina, Nikolay A. Kurkin, Sergei A. Mal’tsev

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G., Gonchar A. V. Tekhnologiya ferritovykh materialov magnitoelektroniki [Technology of ferrite materials of magnetoelectronics]. Moscow, MISiS Publ., 2005, 352 p. (in Russ.) \nPetrova E., Kotsikau D., Pankov V. Structural characterization and magnetic properties of sol–gel derived ZnxFe3-xO4 Journal of Magnetism and Magnetic Materials, 2015, v. 378, pp, 429–435. https://doi.org/10.1016/j.jmmm.2014.11.076 \nMittova I. Ya., Tomina E. V., Lavrushina S. S. Nanomaterialy: sintez nanokristallicheskikh poroshkov i poluchenie kompaktnykh nanokristallicheskikh materialov: uchebnoe posobie dlya vuzov [Nanomaterials: the synthesis of nanocrystalline powders and the production of compact nanocrystalline materials: a textbook for universities]. Voronezh, LOP VGU Publ., 2007, 35 p. (in Russ.) \nBrandon D., Kaplan W. Microstructural Characterization of Materials. Chichester: John Wiley & Sons Ltd, 1999, 424 p. \nTretyakov Yu. D. Development of inorganic chemistry as a fundamental for the design of new generations of functional materials. Russian Chemical Reviews, 2004, v. 73(9), pp. 831–846. https://doi.org/10.1070/RC2004v073n09ABEH000914 \nTomina E. V., Mittova I. Ya., Burtseva N. A., Patent RF, N 2548089, 2015. \nKuznetsova V. A., Almjasheva O. V., Gusarov V. V. Infl uence of microwave and ultrasonic treatment on the formation of CoFe2O4 under hydrothermal conditions. Glass Physics and Chemistry, 2009, v. 35(2), pp. 205–209. \nInternational Center for Diffraction Data. \nShpanchenko R. V., Rozova M. G. Metodicheskaya razrabotka dlya spetspraktikuma k kursu lektsii «Prakticheskie aspekty rentgenovskoi difraktometrii» [Methodical development for the special practical course for lectures “Practical aspects of X-ray diffractometry”]. Moscow, Izd-vo Mosk. un-ta Publ., 1998, 25 p. (in Russ.) \nTret’yakov Yu. D. Neorganicheskaya khimiya. 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引用次数: 2

摘要

微波辐射是由镍制成的正交微粒合成过程中激活的，这意味着大量提高过程速度，降低退火温度，合成样品的高化学同质性。根据当地x射线光谱显微分析，实际的营养水平略低于名义水平，最高的营养水平为0.12。YFeO3和nihy1 - hfeo3的平均大小在200 - 300纳米范围内。反应性Popkov V. I, almjashiva, almjashiva, almjashiva。俄罗斯拥抱化学杂志，2014年，v87 (2)， pp, 167-171。https://doi.org/10.1134/S1070427214020074 Letyuk l M Kostishin v . G。Gonchar a . v . Tekhnologiya ferritovykh materialov magnitoelektroniki [Technology of ferrite材料of magnetoelectronics]。莫斯科，小姐公共。2005年352个pPetrova E, Kotsikau D, Pankov v和Magnetism, 2015年，v378, pp, 429 - 435。https://doi.org/10.1016/j.jmmm.2014.11.076 Mittova一世Ya。多米纳E. V，拉弗鲁什纳S.拉弗鲁什娜:多米提纳·波洛切夫·波索切夫:多米诺·波索切夫·波索切夫:多米诺·波索索瓦夫:多米诺·波索索瓦夫。Voronezh, LOP VGU Publ。2007年，35个p* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *奇切斯特:约翰·威利和儿子有限公司，1999年，424 p。= =开发= = D. inorganic chemistry的开发是为了纪念新的functional物理系的设计。俄罗斯化学评论，2004年，v73 (9)， pp, 831 - 846。https://doi.org/10.1070/RC2004v073n09ABEH000914 Tomina e . V, Mittova一世Ya。Burtseva na, Patent RF, N 2548089, 2015。Kuznetsova v.a, Almjasheva ov V, Gusarov v.v.v，在hydrothermal conditions下对CoFe2O4形式的惩罚。2009年，v35 (2)， pp, 205 - 209。国际分销数据中心。Shpanchenko R. V, Rozova mg, Rozova mg, Rozova mg。莫斯科，Izd-vo Mosk。un - ta Publ。1998年25个pTret 'yakov Yu。D. Neorganicheskaya khimiya。Khimiya elementov: uchebnik dlya stud。vuzov obuch。po napravleniyu 510500“Khimiya”elements的漫画:为学生准备的textbook。在方向510500“Chemistry”和特别化011000“Chemistry”中，宇宙enrolled。莫斯科，Izd-vo Mosk。un-ta: Akademkniga Publ。2007年，v1 538 p;v2 670 p汤姆娜e V，达林斯基b M，米托瓦i。在微波广播下，in组织性物流，v55(4)， 2021 - 425。https://doi.org/10.1134/S0002337X19040158 (in Russ。)

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Микроволновый синтез ортоферрита иттрия и допирование его никелем

Установлено активирующее действие микроволнового излучения в процессе синтеза нанопорошков ортоферрита иттрия, допированного никелем, заключающеесяв значительном увеличении скорости процесса, снижении температуры отжига, высокой химической гомогенности синтезированных образцов. Реальная степень допирования согласно результатам локального рентгеноспектрального микроанализа оказалась несколько ниже номинальной, максимальная реальная степень допирования составляет 0.12. Средний размер частиц YFeO3 и NiхY1-хFeO3 находится в диапазоне 200–300 нм. REFERENCES Popkov V. I., Almjasheva O. V. Yttrium orthoferrite YFeO3 nanopowders formation under glycine-nitrate combustion conditions. Russian Journal of Applied Chemistry, 2014, v. 87(2), pp. 167-171. https://doi.org/10.1134/S1070427214020074 Letyuk L. M., Kostishin V. G., Gonchar A. V. Tekhnologiya ferritovykh materialov magnitoelektroniki [Technology of ferrite materials of magnetoelectronics]. Moscow, MISiS Publ., 2005, 352 p. (in Russ.) Petrova E., Kotsikau D., Pankov V. Structural characterization and magnetic properties of sol–gel derived ZnxFe3-xO4 Journal of Magnetism and Magnetic Materials, 2015, v. 378, pp, 429–435. https://doi.org/10.1016/j.jmmm.2014.11.076 Mittova I. Ya., Tomina E. V., Lavrushina S. S. Nanomaterialy: sintez nanokristallicheskikh poroshkov i poluchenie kompaktnykh nanokristallicheskikh materialov: uchebnoe posobie dlya vuzov [Nanomaterials: the synthesis of nanocrystalline powders and the production of compact nanocrystalline materials: a textbook for universities]. Voronezh, LOP VGU Publ., 2007, 35 p. (in Russ.) Brandon D., Kaplan W. Microstructural Characterization of Materials. Chichester: John Wiley & Sons Ltd, 1999, 424 p. Tretyakov Yu. D. Development of inorganic chemistry as a fundamental for the design of new generations of functional materials. Russian Chemical Reviews, 2004, v. 73(9), pp. 831–846. https://doi.org/10.1070/RC2004v073n09ABEH000914 Tomina E. V., Mittova I. Ya., Burtseva N. A., Patent RF, N 2548089, 2015. Kuznetsova V. A., Almjasheva O. V., Gusarov V. V. Infl uence of microwave and ultrasonic treatment on the formation of CoFe2O4 under hydrothermal conditions. Glass Physics and Chemistry, 2009, v. 35(2), pp. 205–209. International Center for Diffraction Data. Shpanchenko R. V., Rozova M. G. Metodicheskaya razrabotka dlya spetspraktikuma k kursu lektsii «Prakticheskie aspekty rentgenovskoi difraktometrii» [Methodical development for the special practical course for lectures “Practical aspects of X-ray diffractometry”]. Moscow, Izd-vo Mosk. un-ta Publ., 1998, 25 p. (in Russ.) Tret’yakov Yu. D. Neorganicheskaya khimiya. Khimiya elementov: uchebnik dlya stud. vuzov, obuch. po napravleniyu 510500 “Khimiya” i spetsial’nosti 011000 “Khimiya” : v 2 t [Inorganic chemistry. Chemistry of elements: a textbook for students. universities enrolled in the direction 510500 “Chemistry” and specialization 011000 “Chemistry”: in 2 volumes]. Moscow, Izd-vo Mosk. un-ta: Akademkniga Publ., 2007, v. 1, 538 p.; v. 2, 670 p. (in Russ.) Tomina E. V., Darinskii B. M., Mittova I. Ya., Churkin V. D., Boikov N. I., Ivanova O. V. Sintez nanokristallov YСоxFe1-xO3 pod vozdeistviem mikrovolnovogo izlucheniya [Synthesis of YСоxFe1-xO3 Nanocrystals Under the Microwave Radiation], Inorganic Materials, v. 55(4), 2019, pp. 421–425. https://doi.org/10.1134/S0002337X19040158 (in Russ.)

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Kondensirovannye sredy i mezhfaznye granitsy = Condensed Matter and Interphases

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