Home     News     Research     Team     Publications     Media     Contacts  
Polymeric membranes
Laboratory

Leading laboratory on development of polymeric membranes
and processes of gas and liquid separation






Новицкий Эдуард Григорьевич


<< Назад
Новицкий Эдуард Григорьевич
Ведущий научный сотрудник (к.х.н.)

Год рождения: 1937

ORCID: 0000-0001-9009-2073
Scopus Author ID: 24543483900
SPIN: 6635-5010



Образование
  • 1960 г. - Московский институт тонких химических технологий имени М.В. Ломоносова (специальность - высокомолекулярные соединения);
  • 1966 г. - кандидат химических наук, Государственный научно-исследовательский институт химии и технологии элементоорганических соединений ГНИИХТЭОС.

Профессиональная карьера
  • 1960–1968 – научный сотрудник, старший научный сотрудник, ГНИИХТЭОС
  • 1968–1978 – старший научный сотрудник, ИНХС РАН
  • 1978-1990 – начальник сектора «Мембранное разделение газов», ВНИИХИММАШ
  • 1990-2008 – начальник отдела «Мембранные и природоохранные технологии», ВНИИХИММАШ
  • 2008–н.в. – ведущий научный сотрудник ИНХС РАН

Награды
  • -

Области интересов
  • Технологические процессы регенерации абсорбентов углекислого газа; мембраны и мембранные методы очистки и разделения жидкостей и газов; электромембранная очистка водных растворов алканоламинов.

Патенты
  • Э.Г.Новицкий, В.П.Василевский, Е.А.Грушевенко, А.В.Волков, В.В.Волков, С.Д.Баженов. Способ удаления диоксида углерода из газовых смесей. Патент РФ №2656661 от 06.06.2018 г. Бюл. №16
  • В.В.Волков, И.Л.Борисов, В.П.Василевский, Э.Г.Новицкий, А.В.Волков. Мембранный дистилляционный модуль и способ опреснения минерализованной воды. Патент РФ № 2612701 от 03.11.2015
  • Э.Г.Новицкий, Г.А.Дибров, В.П.Василевский, А.В.Волков, А.А.Лысенко, В.С.Хотимский, В.В.Волков. Композиционная мембрана на основе высокопроницаемых стеклообразных полимеров. Патент РФ № 2491983 от 10.09.2013

Публикации
  • E.G.Novitsky, E.A.Grushevenko, I.L.Borisov, T.S.Anokhina, S.D.Bazhenov. Monoethanolamine (MEA) Degradation: Influence on the Electrodialysis Treatment of MEA-Absorbent. Membranes, 13 №5 (2023) 491
  • S.A.Legkov, G.N.Bondarenko, J.V.Kostina, E.G.Novitsky, S.D.Bazhenov, A.V.Volkov, V.V.Volkov. Structural Features of Monoethanolamine Aqueous Solutions with Various Compositions: A Combined Experimental and Theoretical Study Using Vibrational Spectroscopy. Molecules, 28 №1 (2023) 403
  • E.S.Dmitrieva, T.S.Anokhina, E.G.Novitsky, V.V.Volkov, I.L.Borisov, A.V.Volkov. Polymeric Membranes for Oil-Water Separation: A Review. Polymers, 14 №5 (2022) 980
  • E.G.Novitsky, S.D.Bazhenov, A.V.Volkov. Optimization of methods for cleaning gas mixtures from carbon dioxide (Review). Petroleum Chemistry, 61 №3 (2021) 291-310 (in Russian)
  • M.I.Kostyanaya, E.G.Novitskii, S.D.Bazhenov. CO2 Absorption/Desorption on Gas-Liquid Membrane Contactors Using Monoethanolamine Solvent: Comparison of Porous and Composite Hollow Fibers. Key Engineering Materials, 869 (2020) 321-335
  • E.G.Novitsky, E.A.Grushevenko, V.P.Vasilevsky, A.V.Volkov. Studying the Possibilities of Generating Electric-Power by Reverse Electrodialysis of Monoethanolamine Aqueous Solutions. Membranes and Membrane Technologies, 10 №2 (2020) 125-130 (in Russian)
  • E.G.Novitsky, E.A.Grushevenko, V.P.Vasilevsky, A.V.Volkov. Studying the Possibilities of Generating Electric-Power by Reverse Electrodialysis of Monoethanolamine Aqueous Solutions. Membranes and Membrane Technologies, 2 (2020) 109-114
  • E.G.Novitsky, G.S.Golubev, E.A.Grushevenko, V.P.Vasilevsky, A.V.Volkov. Process of Concentrating of Highly Mineralized Waters in an Air-Gap Membrane Distiller. Membranes and Membrane Technologies, 9 №6 (2019) 445-450 (in Russian)
  • E.G.Novitsky, G.S.Golubev, E.A.Grushevenko, V.P.Vasilevsky, A.V.Volkov. Process of Concentrating of Highly Mineralized Waters in an Air-Gap Membrane Distiller. Membranes and Membrane Technologies, 1 №6 (2019) 381-385
  • E.Grushevenko, S.Bazhenov, V.Vasilevsky, E.Novitsky, M.Shalygin, A.Volkov. Effect of Carbon Dioxide Loading on Removal of Heat Stable Salts from Amine Solvent by Electrodialysis. Membranes, 9 №11 (2019) 152
  • S.D.Bazhenov, E.G.Novitskii, V.P.Vasilevskii, E.A.Grushevenko, A.A.Bienko, A.V.Volkov. Heat-Stable Salts and Methods for Their Removal from Alkanolamine Carbon Dioxide Absorbents (Review). Russian Journal of Applied Chemistry, 92 №8 (2019) 1045-1063
  • S.D.Bazhenov, E.G.Novitskii, V.P.Vasilevskii, E.A.Grushevenko, A.A.Bienko, A.V.Volkov. Heat-Stable Salts and Methods for Their Removal from Alkanolamine Carbon Dioxide Absorbents (Review). Russian Journal of Applied Chemistry, 92 №8 (2019) 957-979 (in Russian)
  • E.G.Novitskii, V.P.Vasilevskii, V.I.Vasil’eva, E.A.Goleva, E.A.Grushevenko, A.V.Volkov. Effect of Composition and Structure of Aqueous Monoethanolamine Solutions on Carbon Dioxide Sorption and Desorption in Purification of Gas Mixtures. Russian Journal of Applied Chemistry, 91 №5 (2018) 700–708
  • E.G.Novitskii, V.P.Vasilevskii, V.I.Vasil’eva, E.A.Goleva, E.A.Grushevenko, A.V.Volkov. Effect of Composition and Structure of Aqueous Monoethanolamine Solutions on Carbon Dioxide Sorption and Desorption in Purification of Gas Mixtures. Russian Journal of Applied Chemistry, 91 №5 (2018) 813–821(in Russian)
  • E.A.Grushevenko, S.D.Bazhenov, V.P.Vasilevskii, E.G.Novitskii, A.V.Volkov. Two-step electrodialysis treatment of monoethanolamine to remove heat stable salts. Russian Journal of Applied Chemistry, 91 №4 (2018) 602-610
  • E.G.Novitskii, V.P.Vasilevskii, E.A.Grushevenko, A.V.Volkov, V.I.Vasil’eva. The Effect of Monoethanolamine on Conductivity and Efficiency of Electrodialysis of Acid and Salt Solutions. Russian Journal of Electrochemistry, 53 №4 (2017) 391–397
  • E.G.Novitskii, V.P.Vasilevskii, E.A.Grushevenko, A.V.Volkov, V.I.Vasil’eva. The Effect of Monoethanolamine on Conductivity and Efficiency of Electrodialysis of Acid and Salt Solutions. Russian Journal of Electrochemistry, 53 №4 (2017) 445–451 (in Russian)
  • A.O.Malakhov, E.E.Knyazeva, E.G.Novitsky. Gas transport properties of LiA type zeolite-filled poly(trimethylsilylpropyne) membranes. Petroleum Chemistry. 55 №9 (2015) 708–715
  • A.O.Malakhov, E.E.Knyazeva, E.G.Novitsky. Gas Transport Properties of LiA Zeolite Filled Polytrimethylsilylpropyne. Membranes and membrane technologies. 5 №3 (2015) 183–191 (in Russian)
  • A.O.Malakhov, G.A.Dibrov, E.G.Litvinova, E.G.Novitsky. Gas permeability of homogeneous and composite membranes based on poly(trimethylsilylpropyne)/poly(vinyltrimethylsilane) blends. Petroleum Chemistry. 55 №10 (2015) 803-809
  • A.O.Malakhov, G.A.Dibrov, E.G.Litvinova, E.G.Novitsky. Gas Permeability of Homogeneous and Composite Membranes Based on Poly(trimethylsilylpropyne)/Poly(vinyltrimethylsilane) Blends. Membranes and membrane technologies, 5 №4 (2015) 291–297 (in Russian)
  • G.A.Dibrov, E.G.Novitsky, V.P.Vasilevsky, V.V.Volkov. Cold Rolling for Controllable Narrowing of Pore Size and Pore Size Distribution of Commercial Fluoroplastic Microfiltration Membrane. Petroleum Chemistry. 54 №7 (2014) 568–572
  • G.A.Dibrov, E.G.Novitsky, V.P.Vasilevsky, V.V.Volkov. Cold Rolling for Controllable Narrowing of Pore Size and Pore Size Distribution of Commercial Fluoroplastic Microfiltration Membrane. Membranes and membrane technologies, 4 №1 (2014) 60-65 (in Russian)
  • S.D.Bazhenov, G.A.Dibrov, E.G.Novitsky, V.P.Vasilevsky, V.V.Volkov. Effect of absorbent vapor on stability of characteristics of a composite PTMSP membrane on nonwoven polyester support during regeneration of diethanolamine solution in membrane contactor. Petroleum Chemistry, 54 №8 (2014) 617-621
  • S.D.Bazhenov, G.A.Dibrov, E.G.Novitsky, V.P.Vasilevsky, V.V.Volkov. Effect of absorbent vapor on stability of characteristics of a composite PTMSP membrane on nonwoven polyester support during regeneration of diethanolamine solution in membrane contactor. Membranes and membrane technologies, 4 №3 (2014), 202-207 (in Russian)
  • E.G.Novitsky, V.P.Vasilevsky, S.D.Bazhenov, E.A.Grushevenko, V.I.Vasilyeva, A.V.Volkov. Influence of the composition of concentrate solutions on the efficiency of carbon dioxide removal from monoethanolamine aqueous solution by electrodialysis. Petroleum Chemistry, 54 №8 (2014) 680–685
  • E.G.Novitsky, V.P.Vasilevsky, S.D.Bazhenov, E.A.Grushevenko, V.I.Vasilyeva, A.V.Volkov. Influence of the composition of concentrate solutions on the efficiency of carbon dioxide removal from monoethanolamine aqueous solution by electrodialysis. Membranes and membrane technologies, 4 №4 (2014) 280-286 (in Russian)
  • V.V.Volkov, A.V.Bildukevich, G.A.Dibrov, V.V.Usoskiy, V.P.Kasperchik, V.P. asilevsky, E.G.Novitsky. Elaboration of Composite Hollow Fiber Membranes with Selective Layer from Poly[1-(Trimethylsylil)1-Propyne] for Regeneration of Aqueous Alkanolamine Solutions. Petroleum Chemistry, 53 №8 (2013) 619–626
  • V.V.Volkov, A.V.Bildukevich, G.A.Dibrov, V.V.Usoskiy, V.P.Kasperchik, V.P.Vasilevsky, E.G.Novitsky. Elaboration of Composite Hollow Fiber Membranes with Selective Layer from Poly[1-(Trimethylsylil)1-Propyne] for Regeneration of Aqueous Alkanolamine Solutions. Membranes and membrane technologies, 3 №4 (2013) 252-260 (in Russian)
  • T.V.Eliseeva, E.V.Krisilova, V.P.Vasilevsky, E.G.Novitsky. Electrodialysis of solutions of tartaric acid and its salts. Petroleum Chemistry, 52 №8 (2012) 609-613
  • T.V.Eliseeva, E.V.Krisilova, V.P.Vasilevsky, E.G.Novitsky. Electrodialysis of solutions of tartaric acid and its salts. Membranes and membrane technologies, 2 №3 (2012) 173-178 (in Russian)
  • V.V.Volkov, A.V.Bildukevich, A.N.Filippov, I.V.Vorotyntsev, G.A.Dibrov, V.V.Usoskiy, V.P.Kasperchik, V.P.Vasilevsky, E.G.Novitsky. Composite hollow fiber membranes with diffusion layers of polytrimethylsylilpropyne. Proceedings of R.E.Alekseev Nizhny Novgorod State Technical University, 78 №4 (2012) 280-286
  • A.A.Lysenko, S.D.Bazhenov, V.P.Vasilevsky, E.G.Novitsky, A.V.Volkov. Membrane regeneration of water solution of monoethanolamine. Membranes and membrane technologies, V.2, №4, (2012), 1–6 (in Russian)
  • V.V.Volkov, G.A.Dibrov, A.O.Malakhov, E.G.Novitsky, V.P.Vasilevsky, R.E.Trifonov, N.A.Povarov, V.A.Ostrovsky. Polymeric membranes based on poly-2-methyl-5-vinyltetrazol: synthesis and gas transport properties. Chemical industry, 89 (2012) 321-326 (in Russian)
  • V.P.Vasilevskii, E.G.Novitsky. Electromembrane separation and concentration of lactic acid from fermentation products. Krit. technol. Membrany, 47 №3 (2010) 15 (in Russian)
  • V.P.Vasilevskii, E.G.Novitskii, V.V.Volkov. Electromembrane regeneration of amine solutions from gas processing industries. Krit. technol. Membrany 44 (2009) 14-17 (in Russian)


All rights reserved © 2005-2021 Polymeric Membranes Laboratory