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Стаья
Статья
Статья
O.I. Slavgorodskaya, V.G. Bondaletov, A.A. Lyapkov, J.P. Ustimenko, D. Vervacke. Kinetics of Petroleum Resin Epoxidation by Peracetic Acid. / Procedia Chemistry. – 2014. – Volume 10. – Pages 555-559.
Ляпков А.А., и др. Исследование динамики процесса окисления ДЦПД с различными стабилизирующими добавками методом ИКС / Ф.И. 2013. №8. С.700-703
Ляпков А. А. и др. Математическое моделирование реактора для проведения растворной полимеризации дициклопентадиена / Ф.И. 2013. №8–3. C.655–659
Lyapkov A.A., Melnik (Ionova) E.I., Bondaletov V.G., Pestryakov A.N. Modeling of Oligomerization of C9 Fraction of Petrol Pyrolysis // Advanced Materials Research. – 2013. – Vol. 772. – P. 292–296.
Lyapkov A.A., Bondaletov V.G., Ionova E.I., Borisov G.V. Modeling of the Kinetic Experiment of Dicyclopentadiene Olygomerization. / Advanced Materials Research. - 2014 - Vol. 880. - p. 205-211.
Lyapkov A.A., at all. Kinetics of the Metathesis Polymerization of 5,6–Di(methoxycarbonyl)bicyclo[2.2.1]hept–2–enes on an Original Hoveyda–Grubbs II Type Catalyst // Kinetics and Catalysis, 2013, Vol. 54, No. 4, pp. 469–474.
Lyapkov A.A. at all. The relative reactivity of 2,3-dicarbomethoxy-5-norbornenes in metathesis polymerization using the original n-chelating ruthenium carbene complex / J. Appl. Polym. Sci. 2014, 131, 40130.
Монография
This book comprises the contributions of several authors in the area of polymer characterization by atomic force microscopy of the polymer network structure formed in Ferroelectric Liquid Crystals Cells; polymerization by microwave irradiation method
B.Yu, Y.Xie, F.B. Hamad, K.Leus, A.A. Lyapkov, K.Van Hecke, F.Verpoort. Synthesis and characterization of non-chelating ruthenium–indenylidene olefin metathesis catalysts derived from substituted 1,1-diphenyl-2-propyn-1-ols. NJC, 2015; 39(3)
Adeel H. Chughtai, Nazir Ahmad, Hussein A. Younus, Alex A. Laypkov, Francis Verpoort . Metal–organic frameworks: versatile heterogeneous catalysts for efficient catalytic organic transformations / Chemical Society Reviews 05/2015
B.Yu, F.B.Hamad, K.Leus, A.A.Lyapkov, K.Van Hecke, F.Verpoort. Alkyl group-tagged ruthenium indenylidene complexes: Synthesis, characterization and metathesis activity. J.Org-met.Chem.,2015,791,148–154.
G.S. Bozhenkova, A.P. Samochernova, R.V. Ashirov, A.A. Lyapkov. Polymers Based on Norbornene Derivatives. Procedia Chemistry 2015. 15:8-13.
Alex A. Lyapkov, Francis Verpoort at all. Reactivity of norbornene esters in ring-opening metathesis polymerization initiated by a N-chelating Hoveyda II type catalyst. RSC Advances 2016. 6:5177-5183.
A.A.Lyapkov. Novel Polymers Based on Dimethyl Esters of Norbornene Dicarboxylic Acids Synthesized Using Metathesis Ring-Opening Polymerization // COS, 2017, V.14, №3, P.383-388
A.Lyapkov, S.Kiselev, G.Bozhenkova, O.Kukurina, M.Yusubov, F.Verpoort. Ring Opening Metathesis Polymerization. (Chapter 2 in Recent Research in Polymerization. Intech. 2018. P.15-43)
The purpose of this book is to help you concentrate on recent developments in polymerization. The chapters collected in the book are contributions by invited researchers with a long-standing experience in different research areas. I hope that the material presented here is understandable to a broad audience, not only chemists but also scientists from various disciplines. The book contains nine chapters in three sections: (1) "General Information about Polymerization," (2) "Biomaterial Content Polymer Composites," and (3) "Mechanical Properties of Polymerization." The book provides detailed and current reviews in these different areas written by experts in their respective fields. This book is expected to be useful for polymer workers and other scientists alike and contribute to the training of current and future researchers, academics, PhD degree students, as well as other scientists.
Alexey Lyapkov and all. METATHESIS REACTIONS IN POLYMER SYNTHESIS. New Materials, Compounds and Applications. Vol.2, No.3, 2018, pp.196-220
A.A.Lyapkov at all. Synthesis of polydicyclopentadiene using the Cp2TiCl2/Et2AlCl catalytic system and thin-layer oxidation of the polymer in air. Beilstein J. Org. Chem. 2019, 15, 733–745. doi:10.3762/bjoc.15.69
A.A. Lyapkov and all. Kinetics of Dicyclopentadiene Polymerization in the Presence of the Second Generation Hoveyda-Grubbs Catalyst with N-Chelating Ligand. Polymer Science, Series C. 2019; 61: 41-48
A.A. Lyapkov and all. Relative Reactivity of Dicyclopentadiene and 2,3-Dicarbomethoxy-5-norbornene in Metathesis Copolymerization and the Properties of the Copolymer. Polymer Science, Series C. 2019; 61: 49–57
M.Yu. Kozhanova and all. Dependence of the Mechanical Properties of Polycyclopentadiene Radiation-Modified with Accelerated Electrons on the Content of the Gel Fraction. Polymer Science, Series B. 2019; 61: 771–775
A.A. Lyapkov and all. Low-density polydicyclopentadiene through the use of microspheres. Journal of Polymer Research. 2020; 27: 178(1-10)
Maria V.Zykova and all. New artificial network model to estimate biological activity of peat humic acids. Environmental Research. 2020; 191: 109999(1-6)
M.Yu. Kozhanova at all. Study of Dependence of the Mechanical Properties of Polydicyclopentadiene Irradiated with Electron and γ Radiation. Polymer Science, Series A . 2021. 63(1):39-44. DOI: 10.1134/S0965545X21010041
Ivan A. Sherstobitov at all. Synthesis and characterization of a novel latent ring-opening metathesis polymerization catalyst. Tetrahedron Letters Volume 84, 9 November 2021, 153451