Home / Publications / Organic and hybrid systems: from science to practice

Organic and hybrid systems: from science to practice

Sergey Andreevich Yakukhnov 1
Sergey Andreevich Yakukhnov
Vitalij Vladimirovich Levin 1
Vitalij Vladimirovich Levin
Mikhail Petrovich Egorov 1
Mikhail Petrovich Egorov
Sergey Sergeevich Karlov 1
Sergey Sergeevich Karlov
Andrey Leonidovich Tarasov 1
Andrey Leonidovich Tarasov
Alexander Avraamovich Greish 1
Alexander Avraamovich Greish
Anastasiya Alekseevna Shesterkina 1
Anastasiya Alekseevna Shesterkina
Alexey Mikhailovich Sakharov 1
Alexey Mikhailovich Sakharov
Zinaida Nikolaevna Nysenko 1
Zinaida Nikolaevna Nysenko
Aleksei Borisovich Sheremetev 1
Aleksei Borisovich Sheremetev
Aleksandr Yurevich Stakheev 1
Aleksandr Yurevich Stakheev
Alexey Yu Sukhorukov 1
Alexey Yu Sukhorukov
Sema Leibovich Ioffe 1
Sema Leibovich Ioffe
Roman Aleksandrovich Novikov 1
Roman Aleksandrovich Novikov
Sergei Grigorievich Zlotin 1
Sergei Grigorievich Zlotin
Alexander Sergeevich Kucherenko 1
Alexander Sergeevich Kucherenko
Nadezhda Evgenievna Ustyuzhanina 1
Nadezhda Evgenievna Ustyuzhanina
Vadim Borisovich Krylov 1
Vadim Borisovich Krylov
Yury Evgen'evich Tsvetkov 1
Yury Evgen'evich Tsvetkov
Marina Leonidovna Gening 1
Marina Leonidovna Gening
Nikolay Eduardovich Nifantiev 1
Nikolay Eduardovich Nifantiev
10.1016/j.mencom.2017.09.001
Published 2017-09-07
Focus articleVolume 27, Issue 5, 425-438
89
Share
Cite this
GOST
 | 
Cite this
GOST Copy
Ananikov V. P. et al. Organic and hybrid systems: from science to practice // Mendeleev Communications. 2017. Vol. 27. No. 5. pp. 425-438.
GOST all authors (up to 50) Copy
Ananikov V. P., Eremin D. B., Yakukhnov S. A., Dilman A. D., Levin V. V., Egorov M. P., Karlov S. S., Kustov L. M., Tarasov A. L., Greish A. A., Shesterkina A. A., Sakharov A. M., Nysenko Z. N., Sheremetev A. B., Stakheev A. Y., Mashkovsky I. S., Sukhorukov A. Yu., Ioffe S. L., Terent'ev A. O., Vil' V. A., Tomilov Y. V., Novikov R. A., Zlotin S. G., Kucherenko A. S., Ustyuzhanina N. E., Krylov V. B., Tsvetkov Y. E., Gening M. L., Nifantiev N. E. Organic and hybrid systems: from science to practice // Mendeleev Communications. 2017. Vol. 27. No. 5. pp. 425-438.
RIS
 | 
Cite this
RIS Copy
TY - JOUR
DO - 10.1016/j.mencom.2017.09.001
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.09.001
TI - Organic and hybrid systems: from science to practice
T2 - Mendeleev Communications
AU - Ananikov, Valentin Pavlovich
AU - Eremin, Dmitrii Borisovich
AU - Yakukhnov, Sergey Andreevich
AU - Dilman, Alexander Davidovich
AU - Levin, Vitalij Vladimirovich
AU - Egorov, Mikhail Petrovich
AU - Karlov, Sergey Sergeevich
AU - Kustov, Leonid Modestovich
AU - Tarasov, Andrey Leonidovich
AU - Greish, Alexander Avraamovich
AU - Shesterkina, Anastasiya Alekseevna
AU - Sakharov, Alexey Mikhailovich
AU - Nysenko, Zinaida Nikolaevna
AU - Sheremetev, Aleksei Borisovich
AU - Stakheev, Aleksandr Yurevich
AU - Mashkovsky, Igor' Sergeevich
AU - Sukhorukov, Alexey Yu
AU - Ioffe, Sema Leibovich
AU - Terent'ev, Alexander Olegovich
AU - Vil', Vera Andreevna
AU - Tomilov, Yury Vasil'evich
AU - Novikov, Roman Aleksandrovich
AU - Zlotin, Sergei Grigorievich
AU - Kucherenko, Alexander Sergeevich
AU - Ustyuzhanina, Nadezhda Evgenievna
AU - Krylov, Vadim Borisovich
AU - Tsvetkov, Yury Evgen'evich
AU - Gening, Marina Leonidovna
AU - Nifantiev, Nikolay Eduardovich
PY - 2017
DA - 2017/09/07
PB - Mendeleev Communications
SP - 425-438
IS - 5
VL - 27
ER -
BibTex
 | 
Cite this
BibTex (up to 50 authors) Copy
@article{2017_Ananikov,
author = {Valentin Pavlovich Ananikov and Dmitrii Borisovich Eremin and Sergey Andreevich Yakukhnov and Alexander Davidovich Dilman and Vitalij Vladimirovich Levin and Mikhail Petrovich Egorov and Sergey Sergeevich Karlov and Leonid Modestovich Kustov and Andrey Leonidovich Tarasov and Alexander Avraamovich Greish and Anastasiya Alekseevna Shesterkina and Alexey Mikhailovich Sakharov and Zinaida Nikolaevna Nysenko and Aleksei Borisovich Sheremetev and Aleksandr Yurevich Stakheev and Igor' Sergeevich Mashkovsky and Alexey Yu Sukhorukov and Sema Leibovich Ioffe and Alexander Olegovich Terent'ev and Vera Andreevna Vil' and Yury Vasil'evich Tomilov and Roman Aleksandrovich Novikov and Sergei Grigorievich Zlotin and Alexander Sergeevich Kucherenko and Nadezhda Evgenievna Ustyuzhanina and Vadim Borisovich Krylov and Yury Evgen'evich Tsvetkov and Marina Leonidovna Gening and Nikolay Eduardovich Nifantiev},
title = {Organic and hybrid systems: from science to practice},
journal = {Mendeleev Communications},
year = {2017},
volume = {27},
publisher = {Mendeleev Communications},
month = {Sep},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.09.001},
number = {5},
pages = {425--438},
doi = {10.1016/j.mencom.2017.09.001}
}
MLA
Cite this
MLA Copy
Ananikov, Valentin Pavlovich, et al. “Organic and hybrid systems: from science to practice.” Mendeleev Communications, vol. 27, no. 5, Sep. 2017, pp. 425-438. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.09.001.
Views / Downloads
1 / 2

Abstract

Organic systems still dominate several traditional areas of chemical science and well-known applications, such as the synthesis of pharmaceutical compounds and drugs. However, a fascinating trend has appeared recently to combine pure organic systems into advanced molecular architectures and to create hybrid molecular systems. These interdisciplinary areas, where possible connections between organic and hybrid systems may be developed, are the focus of the present review to develop valuable practical applications.

References

1.
Modern organic synthesis
Egorov M.P.
Russian Chemical Reviews, 2014
2.
The reasons organic chemistry is needed for in a well developed country
Beletskaya I.P., Ananikov V.P.
Russian Journal of Organic Chemistry, 2015
3.
Why organic chemistry is important for a physical chemist?
Kustov L.M.
Russian Journal of Organic Chemistry, 2016
4.
10.1016/j.mencom.2017.09.001_bib0020
Nifantiev
Zh. Org. Khim., 2016
5.
Development of new methods in modern selective organic synthesis: Preparation of functionalized molecules with atomic precision
Ananikov V.P., Khemchyan L.L., Ivanova Y.V., Bukhtiyarov V.I., Sorokin A.M., Prosvirin I.P., Vatsadze S.Z., Medved'ko A.V., Nuriev V.N., Dilman A.D., Levin V.V., Koptyug I.V., Kovtunov K.V., Zhivonitko V.V., Likholobov V.A., et. al.
Russian Chemical Reviews, 2014
6.
Catalysis to Build Molecular Complexity with Atomic Precision
Ananikov V., Liu X., Schneider U.
Chemistry - An Asian Journal, 2016
7.
Ananikov V.P., Khokhlova E.A., Egorov M.P., Sakharov A.M., Zlotin S.G., Kucherov A.V., Kustov L.M., Gening M.L., Nifantiev N.E.
Mendeleev Communications, 2015
8.
Ananikov V.P., Galkin K.I., Egorov M.P., Sakharov A.M., Zlotin S.G., Redina E.A., Isaeva V.I., Kustov L.M., Gening M.L., Nifantiev N.E.
Mendeleev Communications, 2016
9.
Cytotoxicity and Mechanism of Action of the Marine-Derived Fungal Metabolite Trichodermamide B and Synthetic Analogues
Jans P.E., Mfuh A.M., Arman H.D., Shaffer C.V., Larionov O.V., Mooberry S.L.
Journal of Natural Products, 2017
11.
Divergent Reactivity of In Situ Generated Metal Azides: Reaction with N ,N -Bis(oxy)enamines as a Case Study
Zhmurov P.A., Khoroshutina Y.A., Novikov R.A., Golovanov I.S., Sukhorukov A.Y., Ioffe S.L.
Chemistry - A European Journal, 2017
12.
Metal-assisted addition of a nitrate anion to bis(oxy)enamines. A general approach to the synthesis of α-nitroxy-oxime derivatives from nitronates
Naumovich Y.A., Buckland V.E., Sen'ko D.A., Nelyubina Y.V., Khoroshutina Y.A., Sukhorukov A.Y., Ioffe S.L.
Organic and Biomolecular Chemistry, 2016
13.
Novel Synthetic Oxazines Target NF-κB in Colon Cancer In Vitro and Inflammatory Bowel Disease In Vivo
Nirvanappa A.C., Mohan C.D., Rangappa S., Ananda H., Sukhorukov A.Y., Shanmugam M.K., Sundaram M.S., Nayaka S.C., Girish K.S., Chinnathambi A., Zayed M.E., Alharbi S.A., Sethi G., Basappa, Rangappa K.S., et. al.
PLoS ONE, 2016
14.
Difluoromethylene Phosphabetaine as an Equivalent of Difluoromethyl Carbanion
Levin V.V., Trifonov A.L., Zemtsov A.A., Struchkova M.I., Arkhipov D.E., Dilman A.D.
Organic Letters, 2014
15.
Nucleophilic Bromo- and Iododifluoromethylation of Aldehydes
Kosobokov M.D., Levin V.V., Struchkova M.I., Dilman A.D.
Organic Letters, 2014
16.
Nucleophilic Bromodifluoromethylation of Iminium Ions
Tsymbal A.V., Kosobokov M.D., Levin V.V., Struchkova M.I., Dilman A.D.
Journal of Organic Chemistry, 2014
17.
Reactions of gem-Difluorinated Phosphonium Salts Induced by Light
Panferova L.I., Tsymbal A.V., Levin V.V., Struchkova M.I., Dilman A.D.
Organic Letters, 2016
18.
Synthesis of 3-Fluoroindoles via Photoredox Catalysis.
Panferova L.I., Smirnov V.O., Levin V.V., Kokorekin V.A., Struchkova M.I., Dilman A.D.
Journal of Organic Chemistry, 2016
19.
Stereoelectronic source of the anomalous stability of bis-peroxides
Gomes G.D., Vil' V., Terent'ev A., Alabugin I.V.
Chemical Science, 2015
21.
Cyclic peroxides as promising anticancer agents: in vitro cytotoxicity study of synthetic ozonides and tetraoxanes on human prostate cancer cell lines
Yaremenko I.A., Syroeshkin M.A., Levitsky D.O., Fleury F., Terent’ev A.O.
Medicinal Chemistry Research, 2016
22.
Terent’ev A.O., Vil’ V.A., Mulina O.M., Pivnitsky K.K., Nikishin G.I.
Mendeleev Communications, 2014
23.
Manganese triacetate as an efficient catalyst for bisperoxidation of styrenes.
Terent'ev A.O., Sharipov M.Y., Krylov I.B., Gaidarenko D.V., Nikishin G.I.
Organic and Biomolecular Chemistry, 2015
24.
Novikov R.A., Tomilov Y.V.
Mendeleev Communications, 2015
25.
Complexes of Donor–Acceptor Cyclopropanes with Tin, Titanium, and Gallium Chlorides — Mechanism Studies
Novikov R.A., Balakirev D.O., Timofeev V.P., Tomilov Y.V.
Organometallics, 2012
26.
A New Type of Donor-Acceptor Cyclopropane Reactivity: The Generation of Formal 1,2- and 1,4-Dipoles
Novikov R.A., Tarasova A.V., Korolev V.A., Timofeev V.P., Tomilov Y.V.
Angewandte Chemie - International Edition, 2014
27.
GaCl3 -Mediated Reactions of Donor-Acceptor Cyclopropanes with Aromatic Aldehydes
Borisov D.D., Novikov R.A., Tomilov Y.V.
Angewandte Chemie - International Edition, 2016
30.
C 2-Symmetric pyrrolidine-derived squaramides as recyclable organocatalysts for asymmetric Michael reactions
Kucherenko A.S., Lisnyak V.G., Kostenko A.A., Kochetkov S.V., Zlotin S.G.
Organic and Biomolecular Chemistry, 2016
32.
Recent Developments in Synthetic Carbohydrate-Based Diagnostics, Vaccines, and Therapeutics.
Fernández-Tejada A., Cañada F.J., Jiménez-Barbero J.
Chemistry - A European Journal, 2015
33.
Glycans in Medicinal Chemistry: An Underexploited Resource
Fernández-Tejada A., Cañada F.J., Jiménez-Barbero J.
ChemMedChem, 2015
34.
The structure of a fucosylated chondroitin sulfate from the sea cucumber Cucumaria frondosa.
Ustyuzhanina N.E., Bilan M.I., Dmitrenok A.S., Shashkov A.S., Nifantiev N.E., Usov A.I.
Carbohydrate Polymers, 2017
35.
Structural characterization of fucosylated chondroitin sulfates from sea cucumbers Apostichopus japonicus and Actinopyga mauritiana.
Ustyuzhanina N.E., Bilan M.I., Dmitrenok A.S., Tsvetkova E.A., Shashkov A.S., Stonik V.A., Nifantiev N.E., Usov A.I.
Carbohydrate Polymers, 2016
36.
Two fucosylated chondroitin sulfates from the sea cucumber Eupentacta fraudatrix.
Ustyuzhanina N.E., Bilan M.I., Dmitrenok A.S., Nifantiev N.E., Usov A.I.
Carbohydrate Polymers, 2017
37.
Structure and biological activity of a fucosylated chondroitin sulfate from the sea cucumber Cucumaria japonica.
Ustyuzhanina N.E., Bilan M.I., Dmitrenok A.S., Shashkov A.S., Kusaykin M.I., Stonik V.A., Nifantiev N.E., Usov A.I.
Glycobiology, 2015
39.
Ustyuzhanina N.E., Fershtat L.L., Gening M.L., Nifantiev N.E., Makhova N.N.
Mendeleev Communications, 2016
40.
Definitive structural assessment of enterococcal diheteroglycan.
Krylov V.B., Gerbst A.G., Argunov D.A., Dmitrenok A.S., Shashkov A.S., Kaczynski Z., Huebner J., Holst O., Nifantiev N.E.
Chemistry - A European Journal, 2014
41.
Pyranoside-into-furanoside rearrangement: new reaction in carbohydrate chemistry and its application in oligosaccharide synthesis.
Krylov V.B., Argunov D.A., Vinnitskiy D.Z., Verkhnyatskaya S.A., Gerbst A.G., Ustyuzhanina N.E., Dmitrenok A.S., Huebner J., Holst O., Siebert H., Nifantiev N.E.
Chemistry - A European Journal, 2014
42.
10.1016/j.mencom.2017.09.001_bib0210
Theilacker
;1;, 2011
43.
The Pyranoside-into-Furanoside Rearrangement of Alkyl Glycosides: Scope and Limitations
Nifantiev N., Krylov V., Argunov D., Vinnitskiy D., Gerbst A., Ustyuzhanina N., Dmitrenok A.
Synlett, 2016
44.
Acid-promoted synthesis of per-O-sulfated fucooligosaccharides related to fucoidan fragments.
Krylov V.B., Kaskova Z.M., Vinnitskiy D.Z., Ustyuzhanina N.E., Grachev A.A., Chizhov A.O., Nifantiev N.E.
Carbohydrate Research, 2011
48.
Lysozyme's lectin-like characteristics facilitates its immune defense function
Zhang R., Wu L., Eckert T., Burg-Roderfeld M., Rojas-Macias M.A., Lütteke T., Krylov V.B., Argunov D.A., Datta A., Markart P., Guenther A., Norden B., Schauer R., Bhunia A., Enani M.A., et. al.
Quarterly Reviews of Biophysics, 2017
49.
Synthesis of the capsular polysaccharide of type 14
Kochetkov N.K., Nifant'ev N.E., Backinowsky L.V.
Tetrahedron, 1987
51.
10.1016/j.mencom.2017.09.001_bib0255
Tsvetkov
Pure Appl. Chem., 2017
53.
The Effect of a BSA Conjugate of a Synthetic Hexasaccharide Related to the Fragment of Capsular Polysaccharide of Streptococcus pneumoniae Type 14 on the Activation of Innate and Adaptive Immune Responses
Akhmatova N.K., Kurbatova E.A., Akhmatov E.A., Egorova N.B., Logunov D.Y., Gening M.L., Sukhova E.V., Yashunsky D.V., Tsvetkov Y.E., Nifantiev N.E.
Frontiers in Immunology, 2016
56.
Ananikov V.P.
Mendeleev Communications, 2016
58.
Modern electron microscopy in the study of chemical systems at the boundary of organic synthesis and catalysis
Bukhtiyarov V.I., Zaikovskii V.I., Kashin A.S., Ananikov V.P.
Russian Chemical Reviews, 2016
59.
10.1016/j.mencom.2017.09.001_bib0295
Yakukhnov
ChemCatChem, 2017
60.
Supported catalysts based on Pd–In nanoparticles for the liquid-phase hydrogenation of terminal and internal alkynes: 1. formation and structure
Markov P.V., Bragina G.O., Baeva G.N., Tkachenko O.P., Mashkovskii I.S., Yakushev I.A., Vargaftik M.N., Stakheev A.Y.
Kinetics and Catalysis, 2016
61.
Supported catalysts based on Pd–In nanoparticles for the liquid- phase hydrogenation of terminal and internal alkynes: 2. catalytic properties
Markov P.V., Bragina G.O., Baeva G.N., Mashkovskii I.S., Rassolov A.V., Yakushev I.A., Vargaftik M.N., Stakheev A.Y.
Kinetics and Catalysis, 2016
62.
Stakheev A.Y., Smirnova N.S., Krivoruchenko D.S., Baeva G.N., Mashkovsky I.S., Yakushev I.A., Vargaftik M.N.
Mendeleev Communications, 2017
63.
Formation of supported intermetallic nanoparticles in the Pd–Zn/α-Al2O3 catalyst
Mashkovsky I.S., Markov P.V., Bragina G.O., Baeva G.N., Bukhtiyarov A.V., Prosvirin I.P., Bukhtiyarov V.I., Stakheev A.Y.
Kinetics and Catalysis, 2017
64.
Intermetallic Pd1–Zn1 nanoparticles in the selective liquid-phase hydrogenation of substituted alkynes
Mashkovsky I.S., Markov P.V., Bragina G.O., Rassolov A.V., Baeva G.N., Stakheev A.Y.
Kinetics and Catalysis, 2017
65.
Catalysis as an important tool of green chemistry
Beletskaya I.P., Kustov L.M.
Russian Chemical Reviews, 2010
66.
Heterogen katalysierte Hydrierung von Kohlendioxid zu Methan unter erhöhten Drücken
Schoder M., Armbruster U., Martin A.
Chemie-Ingenieur-Technik, 2012
69.
10.1016/j.mencom.2017.09.001_bib0345
Kustov
Microwaves in Catalysis: Methodology and Applications, 2016
70.
Pd–Fe nanoparticles stabilized by chitosan derivatives for perchloroethene dechlorination
Kustov L.M., Finashina E.D., Shuvalova E.V., Tkachenko O.P., Kirichenko O.A.
Environmental International, 2011
71.
Gold nanoparticles in environmental catalysis: Influence of the Fe-modified alumina supports on the catalytic behavior of supported gold nanoparticles in CO oxidation in the presence of ammonia
Kirichenko O.A., Davshan N.A., Redina E.A., Kapustin G.I., Mishin I.V., Tkachenko O.P., Kucherov A.V., Kustov L.M.
Chemical Engineering Journal, 2016
72.
Shesterkina A.A., Kirichenko O.A., Kozlova L.M., Kapustin G.I., Mishin I.V., Strelkova A.A., Kustov L.M.
Mendeleev Communications, 2016
73.
Application of silica-supported Fe–Cu nanoparticles in the selective hydrogenation of p-dinitrobenzene to p-phenylenediamine
Shesterkina A.A., Shuvalova E.V., Kirichenko O.A., Strelkova A.A., Nissenbaum V.D., Kapustin G.I., Kustov L.M.
Russian Journal of Physical Chemistry A, 2017
74.
Influence of the thermal treatment conditions and composition of bimetallic catalysts Fe—Pd/SiO2 on the catalytic properties in phenylacetylene hydrogenation
Shesterkina A.A., Kozlova L.M., Kirichenko O.A., Kapustin G.I., Mishin I.V., Kustov L.M.
Russian Chemical Bulletin, 2016
75.
Transformation of Carbon Dioxide
Sakakura T., Choi J., Yasuda H.
Chemical Reviews, 2007
76.
Copolymerization of propylene oxide with carbon dioxide catalyzed by zinc adipate
Sakharov A.M., Il"in V.V., Rusak V.V., Nysenko Z.N., Klimov S.A.
Russian Chemical Bulletin, 2002
77.
Zinc glutarate-mediated copolymerization of CO2 and PO – parameter studies using design of experiments
Marbach J., Nörnberg B., Rahlf A.F., Luinstra G.A.
Catalysis Science and Technology, 2017
78.
Anionic coordination copolymerization of propylene oxide, carbon dioxide, and l-lactide
Nysenko Z.N., Said-Galiev E.E., Ilyin M.M., Rusak V.V., Glazkov A.A., Sakharov A.M.
Russian Chemical Bulletin, 2015
79.
Recent topics in the chemistry of heavier congeners of carbenes
Tokitoh N., Okazaki R.
Coordination Chemistry Reviews, 2000
80.
Controlled Ring-Opening Polymerization of Lactide and Glycolide
Dechy-Cabaret O., Martin-Vaca B., Bourissou D.
Chemical Reviews, 2004
81.
Extending the family of stable heavier carbenes: New tetrylenes based on N,N,O-ligands
Zaitsev K.V., Cherepakhin V.S., Churakov A.V., Peregudov A.S., Tarasevich B.N., Egorov M.P., Zaitseva G.S., Karlov S.S.
Inorganica Chimica Acta, 2016
82.
Synthesis and structural characterization of low-valent group 14 metal complexes based on aminobisphenol ligands
Zaitsev K.V., Kuchuk E.A., Churakov A.V., Navasardyan M.A., Egorov M.P., Zaitseva G.S., Karlov S.S.
Inorganica Chimica Acta, 2017
83.
10.1016/j.mencom.2017.09.001_bib0415
Zaitsev
Izv. Akad. Nauk, Ser. Khim., 2017
84.
Low-temperature CO oxidation by transition metal polycation exchanged low-silica faujasites
Tkachenko O.P., Greish A.A., Kucherov A.V., Weston K.C., Tsybulevski A.M., Kustov L.M.
Applied Catalysis B: Environmental, 2015
85.
IR study of the active sites formed by H2 treatment of Ga/HZSM-5 catalysts
Kanazirev V., Dimitrova R., Price G.L., Khodakov A.Y., Kustov L.M., Kazansky V.B.
Journal of Molecular Catalysis, 1991
87.
10.1016/j.mencom.2017.09.001_bib0440
Tsybulevski
Energy Technol., 2017
88.
Nitrogen-Rich Azoles as High Density Energy Materials
Yin P., Shreeve J.M.
Advances in Heterocyclic Chemistry, 2017
89.
Novel Highly Energetic Pyrazoles:N-Trinitromethyl-Substituted Nitropyrazoles
Dalinger I.L., Vatsadze I.A., Shkineva T.K., Kormanov A.V., Struchkova M.I., Suponitsky K.Y., Bragin A.A., Monogarov K.A., Sinditskii V.P., Sheremetev A.B.
Chemistry - An Asian Journal, 2015
90.
Novel Melt-Castable Energetic Pyrazole: A Pyrazolyl-Furazan Framework Bearing Five Nitro Groups
Dalinger I.L., Suponitsky K.Y., Pivkina A.N., Sheremetev A.B.
Propellants, Explosives, Pyrotechnics, 2016
91.
Dalinger I.L., Shakhnes A.K., Monogarov K.A., Suponitsky K.Y., Sheremetev A.B.
Mendeleev Communications, 2015
92.
Oxygen-Rich 1,2,4-Triazolo[3,4-d]-1,2,4-triazolo[3,4-f]furazano[3,4-b]pyrazines as Energetic Materials
Sheremetev A.B., Korolev V.L., Potemkin A.A., Aleksandrova N.S., Palysaeva N.V., Hoang T.H., Sinditskii V.P., Suponitsky K.Y.
Asian Journal of Organic Chemistry, 2016
93.
Enthalpies of formation of 3,4- and 3,5-dinitro-1-trimethyl-1Н-pyrazoles
Kazakov A.I., Dalinger I.L., Zyuzin I.N., Lempert D.B., Plishkin N.A., Sheremetev A.B.
Russian Chemical Bulletin, 2016
95.
10.1016/j.mencom.2017.09.001_bib0480
Agrawal
Organic Chemistry of Explosives, 2007
96.
10.1016/j.mencom.2017.09.001_bib0485
Wang
Nitric Oxide Donors: For Pharmaceutical and Biological Applications, 2005
97.
Zlotin S.G., Churakov A.M., Luk’yanov O.A., Makhova N.N., Sukhorukov A.Y., Tartakovsky V.A.
Mendeleev Communications, 2015
98.
A.M. ChurakovandV.A. Tartakovsky, New High Nitrogen Heterocycles with the Alternation of Charges: Stability and Strategy of Synthesis, Energetic Materials. Production, Processing and Characterization, 29th International Annual Conference of ICT, Karlsruhe, Germany, 1998, V7.
99.
Synthesis of Tetrazino-tetrazine 1,3,6,8-Tetraoxide (TTTO)
Klenov M.S., Guskov A.A., Anikin O.V., Churakov A.M., Strelenko Y.A., Fedyanin I.V., Lyssenko K.A., Tartakovsky V.A.
Angewandte Chemie - International Edition, 2016
100.
An efficient access to (1H-tetrazol-5-yl)furoxan ammonium salts via a two-step dehydration/[3+2]-cycloaddition strategy
Fershtat L.L., Epishina M.A., Kulikov A.S., Ovchinnikov I.V., Ananyev I.V., Makhova N.N.
Tetrahedron, 2015
101.
Regioselective synthesis of bifuroxanyl systems with the 3-nitrobifuroxanyl core via a one-pot acylation/nitrosation/cyclization cascade
Fershtat L.L., Larin A.A., Epishina M.A., Kulikov A.S., Ovchinnikov I.V., Ananyev I.V., Makhova N.N.
Tetrahedron Letters, 2016
102.
Experimental and kinetic study of the nitration of 2-ethylhexanol in capillary microreactors
Li L., Yao C., Jiao F., Han M., Chen G.
Chemical Engineering and Processing: Process Intensification, 2017
103.
G. W. Nauflett and R. E. Farncomb, Patent US 6177033, 2001.
104.
Prospective Symbiosis of Green Chemistry and Energetic Materials
Kuchurov I.V., Zharkov M.N., Fershtat L.L., Makhova N.N., Zlotin S.G.
ChemSusChem, 2017
105.
M. N. Zharkov, I.V. Kuchurov, I.V. Fomenkov and S. G. Zlotin, Patent RU 2611009, 2017.
106.
Theoretical and NMR-based Conformational Analysis of Phosphodiester-linked Disaccharides
Gerbst A.G., Nikolaev A.V., Yashunsky D.V., Shashkov A.S., Dmitrenok A.S., Nifantiev N.E.
Scientific Reports, 2017
107.
Target-oriented analysis of gaseous, liquid and solid chemical systems by mass spectrometry, nuclear magnetic resonance spectroscopy and electron microscopy
Kachala V.V., Khemchyan L.L., Kashin A.S., Orlov N.V., Grachev A.A., Zalesskiy S.S., Ananikov V.P.
Russian Chemical Reviews, 2013
108.
Tsedilin A.M., Fakhrutdinov A.N., Eremin D.B., Zalesskiy S.S., Chizhov A.O., Kolotyrkina N.G., Ananikov V.P.
Mendeleev Communications, 2015
109.
Critical Influence of 5-Hydroxymethylfurfural Aging and Decomposition on the Utility of Biomass Conversion in Organic Synthesis.
Galkin K.I., Krivodaeva E.A., Romashov L.V., Zalesskiy S.S., Kachala V.V., Burykina J.V., Ananikov V.P.
Angewandte Chemie - International Edition, 2016
111.
Visible light mediated metal-free thiol–yne click reaction
Zalesskiy S.S., Shlapakov N.S., Ananikov V.P.
Chemical Science, 2016