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Advanced energetic materials: novel strategies and versatile applications

Sergei Grigorievich Zlotin 1
Sergei Grigorievich Zlotin
Aleksandr Mikhailovich Churakov 1
Aleksandr Mikhailovich Churakov
Mikhail Petrovich Egorov 1
Mikhail Petrovich Egorov
Ilya Vladimirovich Kuchurov 1
Ilya Vladimirovich Kuchurov
Nina Nikolaevna Makhova 1
Nina Nikolaevna Makhova
Gennady Alexandrovich Smirnov 1
Gennady Alexandrovich Smirnov
Vladimir Alexandrovich Tartakovsky 1
Vladimir Alexandrovich Tartakovsky
10.1016/j.mencom.2021.11.001
Published 2021-11-08
Focus articleVolume 31, Issue 6, 731-749
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Zlotin S. G. et al. Advanced energetic materials: novel strategies and versatile applications // Mendeleev Communications. 2021. Vol. 31. No. 6. pp. 731-749.
GOST all authors (up to 50) Copy
Zlotin S. G., Churakov A. M., Egorov M. P., Fershtat L. L., Klenov M. S., Kuchurov I. V., Makhova N. N., Smirnov G. A., Tomilov Y. V., Tartakovsky V. A. Advanced energetic materials: novel strategies and versatile applications // Mendeleev Communications. 2021. Vol. 31. No. 6. pp. 731-749.
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TY - JOUR
DO - 10.1016/j.mencom.2021.11.001
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.11.001
TI - Advanced energetic materials: novel strategies and versatile applications
T2 - Mendeleev Communications
AU - Zlotin, Sergei Grigorievich
AU - Churakov, Aleksandr Mikhailovich
AU - Egorov, Mikhail Petrovich
AU - Fershtat, Leonid Leonidovich
AU - Klenov, Michael Sergeevich
AU - Kuchurov, Ilya Vladimirovich
AU - Makhova, Nina Nikolaevna
AU - Smirnov, Gennady Alexandrovich
AU - Tomilov, Yury Vasil'evich
AU - Tartakovsky, Vladimir Alexandrovich
PY - 2021
DA - 2021/11/08
PB - Mendeleev Communications
SP - 731-749
IS - 6
VL - 31
ER -
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@article{2021_Zlotin,
author = {Sergei Grigorievich Zlotin and Aleksandr Mikhailovich Churakov and Mikhail Petrovich Egorov and Leonid Leonidovich Fershtat and Michael Sergeevich Klenov and Ilya Vladimirovich Kuchurov and Nina Nikolaevna Makhova and Gennady Alexandrovich Smirnov and Yury Vasil'evich Tomilov and Vladimir Alexandrovich Tartakovsky},
title = {Advanced energetic materials: novel strategies and versatile applications},
journal = {Mendeleev Communications},
year = {2021},
volume = {31},
publisher = {Mendeleev Communications},
month = {Nov},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.11.001},
number = {6},
pages = {731--749},
doi = {10.1016/j.mencom.2021.11.001}
}
MLA
Cite this
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Zlotin, Sergei Grigorievich, et al. “Advanced energetic materials: novel strategies and versatile applications.” Mendeleev Communications, vol. 31, no. 6, Nov. 2021, pp. 731-749. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.11.001.
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Keywords

N-oxides
energetic compounds
energetic materials
explosives
Green chemistry
hypergolic fuels
nitro compounds
powders
propellants
strained hydrocarbons

Abstract

Novel efficient synthetic strategies, including green methodologies, to basic and perspective high-energy density compounds, bearing active oxygen sources (C-, N- and O-nitro groups and N-oxide fragments) and high-enthalpy polynitrogen heterocycles, are briefly overviewed. Recently developed synthetic approaches to nitro group-free hypergolic ionic liquids (HILs) and strained 1,5-diaza- bicyclo[3.1.0]hexane derivatives capable of ultrafast ignition upon mixing with an oxidizer, and to high-energy liquid hydrocarbons with strained cyclopropane fragments are also considered. Physicochemical properties, energetic performances and potential applications of energetic compounds and composites as key components of explosives, powders and solid or liquid rocket propellants are critically discussed with a focus on original reports published in the period 2016–2021.

References

1.
10.1016/j.mencom.2021.11.001_b0005
Fundamentals of Smart Materials, 2020
2.
Smart materials types, properties and applications: A review
Bahl S., Nagar H., Singh I., Sehgal S.
Materials Today: Proceedings, 2020
3.
Materials design by synthetic biology
Tang T., An B., Huang Y., Vasikaran S., Wang Y., Jiang X., Lu T.K., Zhong C.
Nature Reviews Materials, 2020
5.
10.1016/j.mencom.2021.11.001_b0025
Li
J. Hazard. Mater., 2020
6.
10.1016/j.mencom.2021.11.001_b0030
Klapötke
Chemistry of High-Energy Materials, 2019
7.
Recent developments in the field of energetic ionic liquids
Sebastiao E., Cook C., Hu A., Murugesu M.
Journal of Materials Chemistry A, 2014
8.
10.1016/j.mencom.2021.11.001_b0040
High-Energy-Density Fuels for Advanced Propulsion: Design and Synthesis, 2020
9.
“Green” Pyrotechnics: A Chemists' Challenge
Steinhauser G., Klapötke T.
Angewandte Chemie - International Edition, 2008
10.
10.1016/j.mencom.2021.11.001_b0050
Green Energetic Materials, 2014
11.
10.1016/j.mencom.2021.11.001_b0055
Defense Industries: Science and Technology Related to Security: Impact of Conventional Munitions on Environment and Population, 2007
12.
10.1016/j.mencom.2021.11.001_b0060
Zlotin
Mendeleev Commun., 2015
14.
Zlotin S.G., Churakov A.M., Dalinger I.L., Luk’yanov O.A., Makhova N.N., Sukhorukov A.Y., Tartakovsky V.A.
Mendeleev Communications, 2017
15.
10.1016/j.mencom.2021.11.001_b0075
Agrawal
Organic Chemistry of Explosives, 2007
16.
10.1016/j.mencom.2021.11.001_b0080
Meyer
Explosives, 2016
17.
10.1016/j.mencom.2021.11.001_b0085
Klapötke
Energetic Materials Encyclopedia, 2018
18.
Nitro compounds as the core structures of promising energetic materials and versatile reagents for organic synthesis
Zlotin S.G., Dalinger I.L., Makhova N.N., Tartakovsky V.A.
Russian Chemical Reviews, 2020
20.
N-(2-Fluoro-2,2-dinitroethyl)azoles: a novel assembly of diverse explosophoric building blocks for energetic compound design
Palysaeva N.V., Gladyshkin A.G., Vatsadze I.A., Suponitsky K.Y., Dmitriev D.E., Sheremetev A.B.
Organic Chemistry Frontiers, 2019
21.
Dalinger I.L., Shakhnes A.K., Monogarov K.A., Suponitsky K.Y., Sheremetev A.B.
Mendeleev Communications, 2015
22.
Pyrazole-Tetrazole Hybrid with Trinitromethyl, Fluorodinitromethyl, or (Difluoroamino)dinitromethyl Groups: High-Performance Energetic Materials
Dalinger I.L., Kormanov A.V., Suponitsky K.Y., Muravyev N.V., Sheremetev A.B.
Chemistry - An Asian Journal, 2018
23.
Synthesis and Investigation of Advanced Energetic Materials Based on Bispyrazolylmethanes
Fischer D., Gottfried J.L., Klapötke T.M., Karaghiosoff K., Stierstorfer J., Witkowski T.G.
Angewandte Chemie - International Edition, 2016
24.
Bipyrazole bearing ten nitro groups – a novel highly dense oxidizer for forward-looking rocket propulsions
Dalinger I.L., Suponitsky K.Y., Shkineva T.K., Lempert D.B., Sheremetev A.B.
Journal of Materials Chemistry A, 2018
25.
A high density pyrazolo-triazine explosive (PTX)
Schulze M.C., Scott B.L., Chavez D.E.
Journal of Materials Chemistry A, 2015
26.
Nitropyrazoles
Dalinger I.L., Vatsadse I.A., Shkineva T.K., Popova G.P., Ugrak B.I., Shevelev S.A.
Russian Chemical Bulletin, 2010
27.
A C–C bonded 5,6-fused bicyclic energetic molecule: exploring an advanced energetic compound with improved performance
Tang Y., He C., Imler G.H., Parrish D.A., Shreeve J.M.
Chemical Communications, 2018
28.
Balancing Excellent Performance and High Thermal Stability in a Dinitropyrazole Fused 1,2,3,4-Tetrazine
Tang Y., Kumar D., Shreeve J.M.
Journal of the American Chemical Society, 2017
32.
CL-20-Based Cocrystal Energetic Materials: Simulation, Preparation and Performance
Pang W., Wang K., Zhang W., Luca L.T., Fan X., Li J.
Molecules, 2020
35.
PdFe bimetallic catalysts for debenzylation of hexabenzylhexaazaisowurtzitane (HBIW) and tetraacetyldibenzylhexaazaisowurtzitane (TADBIW)
Lou D., Wang H., Liu S., Li L., Zhao W., Chen X., Wang J., Li X., Wu P., Yang J.
Catalysis Communications, 2018
36.
A. I. Kalashnikov, S. V. Sysolyatin, G. V. Sakovich, A. S. Dubkov and D. A. Kulagina, Russ. Chem. Bull., Int. Ed., 2017, 66, 531 (Izv. Akad. Nauk, Ser. Khim., 2017, 531).
37.
Synthesis of CL-20 by a Greener Method Using Nitroguanidine/HNO3
Bayat Y., Hajighasemali F.
Propellants, Explosives, Pyrotechnics, 2016
38.
10.1016/j.mencom.2021.11.001_b0190
Surmachev
Propellants, Explos., Pyrotech., 1841
39.
Application and Properties of CL‐20/HMX Cocrystal in Composite Modified Double Base Propellants
Wu Z., Liu N., Zheng W., Chen J., Song X., Wang J., Cui C., Zhang D., Zhao F.
Propellants, Explosives, Pyrotechnics, 2019
42.
1,2,4,5-Dioxadiazine-functionalized [N–NO2]− furazan energetic salts
Huang H., Shi Y., Liu Y., Yang J.
Dalton Transactions, 2016
44.
Composite energetic salt based on 3-nitramino-4-(1H-tetrazol-5-yl)furazan
Zhao K., Shi Y., Li H., Huang H., Yang J.
Polyhedron, 2020
45.
10.1016/j.mencom.2021.11.001_b0225
Wang
J. Mol. Struct., 2021
46.
Nitrocarbamoyl Azide O2NN(H)C(O)N3: A Stable but Highly Energetic Member of the Carbonyl Azide Family
Benz M., Klapötke T.M., Krumm B., Lommel M., Stierstorfer J.
Journal of the American Chemical Society, 2021
47.
Vinogradov D.B., Bulatov P.V., Petrov E.Y., Tartakovsky V.A.
Mendeleev Communications, 2020
49.
Synthesis of bis-Isoxazole-bis-Methylene Dinitrate: A Potential Nitrate Plasticizer and Melt-Castable Energetic Material
Wingard L.A., Guzmán P.E., Johnson E.C., Sabatini J.J., Drake G.W., Byrd E.F.
ChemPlusChem, 2016
50.
Synthesis of Biisoxazoletetrakis(methyl nitrate): A Potential Nitrate Plasticizer and Highly Explosive Material
Wingard L.A., Johnson E.C., Guzmán P.E., Sabatini J.J., Drake G.W., Byrd E.F., Sausa R.C.
European Journal of Organic Chemistry, 2017
51.
Bis(1,2,4-oxadiazole)bis(methylene) Dinitrate: A High-Energy Melt-Castable Explosive and Energetic Propellant Plasticizing Ingredient
Johnson E.C., Sabatini J.J., Chavez D.E., Sausa R.C., Byrd E.F., Wingard L.A., Guzmàn P.E.
Organic Process Research and Development, 2018
52.
Bis(Nitroxymethylisoxazolyl) Furoxan: A Promising Standalone Melt‐Castable Explosive
Johnson E.C., Sabatini J.J., Chavez D.E., Wells L.A., Banning J.E., Sausa R.C., Byrd E.F., Orlicki J.A.
ChemPlusChem, 2020
53.
Impact of Stereo- and Regiochemistry on Energetic Materials
Barton L.M., Edwards J.T., Johnson E.C., Bukowski E.J., Sausa R.C., Byrd E.F., Orlicki J.A., Sabatini J.J., Baran P.S.
Journal of the American Chemical Society, 2019
55.
O. A. Luk’yanov, N. I. Shlykova, G. V. Pokhvisneva, T. V. Ternikova, S. V. Nikitin, G. A. Smirnov, Yu. V. Nelubina, P. V. Dorovatovskii, T. S. Kon’kova, N. V. Murav’yov and A. N. Pivkina, Russ. Chem. Bull., Int. Ed., 2017, 66, 1066 (Izv. Akad. Nauk, Ser. Khim., 2017, 1066).
56.
Synthesis of 4- and 6-(tetrazolylmethyl)pentanitrohexaazaisowurtzitanes
Ternikova T.V., Pokhvisneva G.V., Luk’yanov O.A.
Russian Chemical Bulletin, 2019
57.
Energetic N-azidomethyl derivatives of polynitro hexaazaisowurtzitanes series: CL-20 analogues having the highest enthalpy
Luk′yanov O.A., Parakhin V.V., Shlykova N.I., Dmitrienko A.O., Melnikova E.K., Kon'kova T.S., Monogarov K.A., Meerov D.B.
New Journal of Chemistry, 2020
59.
Green Synthetic Approach for High-Performance Energetic Nitramino Azoles
Tang Y., Liu Y., Imler G.H., Parrish D.A., Shreeve J.M.
Organic Letters, 2019
60.
Phase and Interface Engineering of Platinum-Nickel Nanowires for Efficient Electrochemical Hydrogen Evolution
Wang P., Jiang K., Wang G., Yao J., Huang X.
Angewandte Chemie - International Edition, 2016
61.
Polynitro‐Functionalized Dipyrazolo‐1,3,5‐triazinanes: Energetic Polycyclization toward High Density and Excellent Molecular Stability
Yin P., Zhang J., Imler G.H., Parrish D.A., Shreeve J.M.
Angewandte Chemie - International Edition, 2017
62.
N-functionalized nitroxy/azido fused-ring azoles as high-performance energetic materials
Zhang J., Yin P., Mitchell L.A., Parrish D.A., Shreeve J.M.
Journal of Materials Chemistry A, 2016
64.
Nitrogen-Rich Azoles as High Density Energy Materials
Yin P., Shreeve J.M.
Advances in Heterocyclic Chemistry, 2017
65.
10.1016/j.mencom.2021.11.001_b0325
Chavez
Heterocyclic N-Oxides, 2017
66.
Progress in 1,2,3,4-Tetrazine Chemistry
Churakov A.M., Tartakovsky V.A.
Chemical Reviews, 2004
67.
Accelerating the discovery of insensitive high-energy-density materials by a materials genome approach
Wang Y., Liu Y., Song S., Yang Z., Qi X., Wang K., Liu Y., Zhang Q., Tian Y.
Nature Communications, 2018
68.
3,30-(Diazene-1,2-diyl)bis[4-(nitroamino)-1,2,5- oxadiazole 2-oxide]
Larin A., Ovchinnikov I., Fershtat L., Makhova N.
MolBank, 2018
69.
Energetic 1,2,5‐Oxadiazolo‐Pyridazine and its N‐Oxide
Tang Y., He C., Imler G.H., Parrish D.A., Shreeve J.M.
Chemistry - A European Journal, 2017
70.
An Energetic Triazolo-1,2,4-Triazine and its N-Oxide
Piercey D.G., Chavez D.E., Scott B.L., Imler G.H., Parrish D.A.
Angewandte Chemie - International Edition, 2016
71.
Synthesis and Properties [1,2,4]Triazolo[4,3‐b][1,2,4,5]Tetrazine N ‐Oxide Explosives
Wang G., Fu Z., Yin H., Chen F.
Propellants, Explosives, Pyrotechnics, 2019
72.
Fused rings with N-oxide and –NH2: good combination for high density and low sensitivity energetic materials
Hu L., Yin P., Imler G.H., Parrish D.A., Gao H., Shreeve J.M.
Chemical Communications, 2019
73.
10.1016/j.mencom.2021.11.001_b0365
Hu
Energy Mater., 2020
74.
Challenging the limits of nitrogen and oxygen content of fused rings
Hu L., Gao H., Shreeve J.M.
Journal of Materials Chemistry A, 2020
75.
A. O. Shvets, A. A. Konnov, M. S. Klenov, A. M. Churakov, Yu. A. Strelenko and V. A. Tartakovsky, Russ. Chem. Bull., Int. Ed., 2020, 69, 739 (Izv. Akad. Nauk, Ser. Khim., 2020, 739).
76.
A furazan-fused pyrazole N-oxide via unusual cyclization
Tang Y., He C., Shreeve J.M.
Journal of Materials Chemistry A, 2017
78.
First Synthesis of Aliphatic Nitro-NNO -azoxy Compounds
Leonov N.E., Klenov M.S., Anikin O.V., Churakov A.M., Strelenko Y.A., Monogarov K.A., Tartakovsky V.A.
European Journal of Organic Chemistry, 2018
79.
Synthesis of New Energetic Materials Based on Furazan Rings and Nitro‐ NNO ‐azoxy Groups
Leonov N.E., Klenov M.S., Anikin O.V., Churakov A.M., Strelenko Y.A., Voronin A.A., Lempert D.B., Muravyev N.V., Fedyanin I.V., Semenov S.E., Tartakovsky V.A.
ChemistrySelect, 2020
80.
M. S. Klenov, N. E. Leonov, A. A. Guskov, A. M. Churakov, Yu. A. Strelenko and V. A. Tartakovsky, Russ. Chem. Bull., Int. Ed., 2019, 68, 1798 (Izv. Akad. Nauk, Ser. Khim., 2019, 1798).
81.
An Energetic (Nitro-NNO -azoxy)triazolo-1,2,4-triazine
Anikin O.V., Leonov N.E., Klenov M.S., Churakov A.M., Voronin A.A., Muravyev N.V., Strelenko Y.A., Fedyanin I.V., Tartakovsky V.A.
European Journal of Organic Chemistry, 2019
82.
Synthesis of nitroxy and nitraza derivatives of 1,1-dinitroalkyldiazene 1-oxides
Ternikova T.V., Pokhvisneva G.V., Luk’yanov O.A.
Russian Chemical Bulletin, 2020
84.
Synthetic and thermal studies of four insensitive energetic materials based on oxidation of the melamine structure
Zhang J., Bi F., Zhang J., Wang X., Yang Z., Zhang G., Wang B.
RSC Advances, 2021
86.
Azido and Tetrazolo 1,2,4,5‐Tetrazine N‐Oxides
Chavez D.E., Parrish D.A., Mitchell L., Imler G.H.
Angewandte Chemie - International Edition, 2017
87.
Polycyclic N-oxides: high performing, low sensitivity energetic materials
Snyder C.J., Wells L.A., Chavez D.E., Imler G.H., Parrish D.A.
Chemical Communications, 2019
88.
Generation of oxodiazonium ions 2. Synthesis of benzotetrazine-1,3-dioxides from 2-(tert-butyl-NNO-azoxy)-N-nitroanilines
Klenov M.S., Zelenov V.P., Churakov A.M., Strelenko Y.A., Tartakovsky V.A.
Russian Chemical Bulletin, 2011
89.
V. P. Zelenov and M. E. Minyaev, Russ. Chem. Bull., Int. Ed., 2021, 70, 369 (Izv. Akad. Nauk, Ser. Khim., 2021, 369).
90.
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
91.
10.1016/j.mencom.2021.11.001_b0455
Politzer
Cent. Eur. J. Energ. Mater., 2013
92.
A. A. Guskov, M. S. Klenov, A. M. Churakov and V. A. Tartakovsky, Russ. Chem. Bull., Int. Ed., 2016, 65, 2763 (Izv. Akad. Nauk, Ser. Khim., 2016, 2763).
93.
Serendipitous Synthesis of (tert-Butyl-NNO-azoxy)acetonitrile: Reduction of an Oxime Moiety to a Methylene Unit
Klenov M.S., Anikin O.V., Guskov A.A., Churakov A.M., Strelenko Y.A., Ananyev I.V., Bushmarinov I.S., Dmitrienko A.O., Lyssenko K.A., Tartakovsky V.A.
European Journal of Organic Chemistry, 2016
94.
Synthesis of 1,2,3,4‐Tetrazine 1,3‐Dioxides Annulated with 1,3 a,4,6 a‐Tetraazapentalene Systems
Konnov A.A., Klenov M.S., Churakov A.M., Strelenko Y.A., Dmitrienko A.O., Puntus L.N., A. Lyssenko K., Tartakovsky V.A.
Asian Journal of Organic Chemistry, 2018
95.
Azole-Based Energetic Salts
Gao H., Shreeve J.M.
Chemical Reviews, 2011
96.
High-energy hydroxytetrazoles: Design, synthesis and performance
Larin A.A., Fershtat L.L.
Energetic Materials Frontiers, 2021
97.
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
98.
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
99.
Assembly of Tetrazolylfuroxan Organic Salts: Multipurpose Green Energetic Materials with High Enthalpies of Formation and Excellent Detonation Performance
Larin A.A., Muravyev N.V., Pivkina A.N., Suponitsky K.Y., Ananyev I.V., Khakimov D.V., Fershtat L.L., Makhova N.N.
Chemistry - A European Journal, 2019
101.
Azasydnones and their use in Energetic Materials
Gettings M., Piercey D.
Energetic Materials Frontiers, 2020
102.
Straightforward Access to the Nitric Oxide Donor Azasydnone Scaffold by Cascade Reactions of Amines
Zhilin E.S., Bystrov D.M., Ananyev I.V., Fershtat L.L., Makhova N.N.
Chemistry - A European Journal, 2019
103.
Azasydnone – novel “green” building block for designing high energetic compounds
Dalinger I.L., Serushkina O.V., Muravyev N.V., Meerov D.B., Miroshnichenko E.A., Kon'kova T.S., Suponitsky K.Y., Vener M.V., Sheremetev A.B.
Journal of Materials Chemistry A, 2018
104.
Tetrazole Azasydnone (C 2 N 7 O 2 H) And Its Salts: High‐Performing Zwitterionic Energetic Materials Containing A Unique Explosophore
Gettings M.L., Thoenen M.T., Byrd E.F., Sabatini J.J., Zeller M., Piercey D.G.
Chemistry - A European Journal, 2020
105.
Heterocyclic Nitrilimines and Their Use in the Synthesis of Complex High-Nitrogen Materials
Gettings M.L., Davis Finch S.E., Sethia A., Byrd E.F., Zeller M., Piercey D.G.
Inorganic Chemistry, 2021
106.
Thermochemistry of Species Potentially Formed During NTO/MMH Hypergolic Ignition
Osmont A., Catoire L., Klapötke T., Vaghjiani G., Swihart M.
Propellants, Explosives, Pyrotechnics, 2008
107.
Critical Ignition Criteria for Monomethylhydrazine and Red Fuming Nitric Acid
Dennis J.D., Son S.F., Pourpoint T.L.
Journal of Propulsion and Power, 2015
108.
Ionic Liquids as Hypergolic Fuels
Schneider S., Hawkins T., Rosander M., Vaghjiani G., Chambreau S., Drake G.
Energy & Fuels, 2008
110.
Dicyanoborate-Based Ionic Liquids as Hypergolic Fluids
Zhang Y., Shreeve J.M.
Angewandte Chemie - International Edition, 2010
111.
Synthesis and Ignition Properties Research of 1,5-Diazabicyclo[3.1.0]Hexane Type Compounds as Potential Green Hypergolic Propellants
Zhang X., Shen L., Luo Y., Jiang R., Sun H., Liu J., Fang T., Fan H., Liu Z.
Industrial & Engineering Chemistry Research, 2017
112.
10.1016/j.mencom.2021.11.001_b0560
Joo
Inorg. Chem., 2010
113.
Synthesis and Properties of Azide‐Functionalized Ionic Liquids as Attractive Hypergolic Fuels
Wang Z., Pan G., Wang B., Zhang L., Zhao W., Ma X., Zhang J., Zhang J.
Chemistry - An Asian Journal, 2019
115.
Cyanoborohydride-Based Ionic Liquids as Green Aerospace Bipropellant Fuels
Zhang Q., Yin P., Zhang J., Shreeve J.M.
Chemistry - A European Journal, 2014
116.
Nitrocyanamide-Based Ionic Liquids and Their Potential Applications as Hypergolic Fuels
He L., Tao G., Parrish D., Shreeve J.
Chemistry - A European Journal, 2010
117.
10.1016/j.mencom.2021.11.001_b0585
Jiao
Chem. – Asian J., 1932
120.
Synthesis and hypergolic properties of flammable ionic liquids based on the cyano (1H-1,2,3-triazole-1-yl) dihydroborate anion
Wang Z., Jin Y., Zhang W., Wang B., Liu T., Zhang J., Zhang Q.
Dalton Transactions, 2019
121.
Rational Design and Facile Synthesis of Boranophosphate Ionic Liquids as Hypergolic Rocket Fuels
Liu T., Qi X., Wang B., Jin Y., Yan C., Wang Y., Zhang Q.
Chemistry - A European Journal, 2018
122.
Bis(borano)hypophosphite-based ionic liquids as ultrafast-igniting hypergolic fuels
Zhang W., Qi X., Huang S., Li J., Tang C., Li J., Zhang Q.
Journal of Materials Chemistry A, 2016
123.
Green Bipropellants: Hydrogen-Rich Ionic Liquids that Are Hypergolic with Hydrogen Peroxide
Schneider S., Hawkins T., Ahmed Y., Rosander M., Hudgens L., Mills J.
Angewandte Chemie - International Edition, 2011
125.
Hypergolic fuels based on water-stable borohydride cluster anions with ultralow ignition delay times
Jiao N., Zhang Y., Liu L., Shreeve J.M., Zhang S.
Journal of Materials Chemistry A, 2017
126.
Nitrato-Functionalized Task-Specific Ionic Liquids as Attractive Hypergolic Rocket Fuels
Wang Y., Huang S., Zhang W., Liu T., Qi X., Zhang Q.
Chemistry - A European Journal, 2017
127.
Effects of closo-icosahedral periodoborane salts on hypergolic reactions of 70% H2O2 with energetic ionic liquids
Chinnam A.K., Petrutik N., Wang K., Shlomovich A., Shamis O., Tov D.S., Sućeska M., Yan Q., Dobrovetsky R., Gozin M.
Journal of Materials Chemistry A, 2018
130.
Oxidation of a Levitated Droplet of 1-Allyl-3-methylimidazolium Dicyanamide by Nitrogen Dioxide
Lucas M., Brotton S.J., Shukla S.K., Yu J., Anderson S.L., Kaiser R.I.
Journal of Physical Chemistry A, 2018
131.
Oxidation of a Levitated 1-Butyl-3-methylimidazolium Dicyanoborate Droplet by Nitrogen Dioxide
Lucas M., Brotton S.J., Sprenger J.A., Finze M., Sharma S.K., Kaiser R.I.
Journal of Physical Chemistry A, 2019
132.
Thermal Decomposition and Hypergolic Reaction of a Dicyanoborohydride Ionic Liquid
Thomas A.E., Chambreau S.D., Redeker N.D., Esparza A.A., Shafirovich E., Ribbeck T., Sprenger J.A., Finze M., Vaghjiani G.L.
Journal of Physical Chemistry A, 2020
136.
Asymmetric nitrogen—41
Shustov G.V., Denisenko S.N., Chervin I.I., Asfandiarov N.L., Kostyanovsky R.G.
Tetrahedron, 1985
137.
V. V. Kuznetsov, S. A. Kutepov, N. N. Makhova, K. A. Lyssenko and D. E. Dmitriev, Russ. Chem. Bull., Int. Ed., 2003, 52, 665 (Izv. Akad. Nauk, Ser. Khim., 2003, 638).
138.
Thermolysis of 6-Aryl-1,5-diazabicyclo[3.1.0]hexanes in the Presence of N-Arylmaleimides
Molchanov A.P., Sipkin D.I., Koptelov Y.B., Kostikov R.R.
Russian Journal of Organic Chemistry, 2001
139.
10.1016/j.mencom.2021.11.001_b0695
Zhang
Chem. Eng. Sci., 2018
140.
10.1016/j.mencom.2021.11.001_b0700
Meshcheryakov
Dokl. Akad. Nauk SSSR, 1960
141.
Free-Radical Polymerization and Ring-Expansion of a Cubane Acrylate: a Unique Low-Shrink Polymer
McGonagle A.E., Savage G.P.
Australian Journal of Chemistry, 2009
142.
Synthesis, High-Resolution Infrared Spectroscopy, and Vibrational Structure of Cubane, C8H8
Boudon V., Lamy M., Dugue-Boyé F., Pirali O., Gruet S., D’Accolti L., Fusco C., Annese C., Alikhani M.E.
Journal of Physical Chemistry A, 2016
144.
Synthesis and properties of the ivyanes: the parent 1,1-oligocyclopropanes
Bojase G., Nguyen T.V., Payne A.D., Willis A.C., Sherburn M.S.
Chemical Science, 2011
145.
The reagent Et2AlX/CH2N2 in cyclopropanation of sterically hindered olefins, as well as oxygen- and nitrogen-containing unsaturated compounds
Ramazanov I.R., Yaroslavova A.V., Yaubasarov N.R., Gil’manova E.N., Dzhemilev U.M.
Russian Chemical Bulletin, 2019
146.
Ramazanov I.R., Kadikova R.N., Zosim T.P., Nadrshina Z.I., Dzhemilev U.M.
Mendeleev Communications, 2016
147.
Recent advances in the catalytic cyclopropanation of unsaturated compounds with diazomethane
Menchikov L.G., Shulishov E.V., Tomilov Y.V.
Russian Chemical Reviews, 2021
149.
Synthesis and properties of high-energy-density hydrocarbons based on 5-vinyl-2-norbornene
Shorunov S.V., Zarezin D.P., Samoilov V.O., Rudakova M.A., Borisov R.S., Maximov A.L., Bermeshev M.V.
Fuel, 2021
150.
Synthesis of strained high-energy rocket bio-kerosene via cyclopropanation of myrcene
Liu Y., Ma C., Shi C., Pan L., Xie J., Gong S., Zhang Y., Nie G., Zhang X., Zou J.
Fuel Processing Technology, 2020
151.
The mechanisms of antifoam action
Kruglyakov P.M.
Russian Chemical Reviews, 1994
152.
Aluminum carbenoids in the cyclopropanation of fulvenes
Ramazanov I.R., Yaroslavova A.V., Yaubasarov N.R., Dzhemilev U.M.
Russian Chemical Bulletin, 2018
153.
Catalytic cyclopropanation of spiro[2.4]hepta-4,6-diene with diazomethane
Shulishov E.V., Pantyukh O.A., Menchikov L.G., Tomilov Y.V.
Tetrahedron Letters, 2019
155.
Thermophysical properties of high energy synthetic hydrocarbons
Yanovskiy L.S., Varlamova N.I., Kazakov A.I., Molokanov A.A., Plishkin N.A.
Journal of Physics: Conference Series, 2019
156.
Unusual rearrangement in the reaction of cyclopropanated cyclopentadienes with Et3Al/CH2I2 in CH2Cl2
Ramazanov I.R., Yaroslavova A.V., Yaubasarov N.R., Dzhemilev U.M.
Synthetic Communications, 2018
157.
10.1016/j.mencom.2021.11.001_b0785
Brinck
Green Energetic Materials, 2014
158.
Environmentally compatible next generation green energetic materials (GEMs)
Talawar M.B., Sivabalan R., Mukundan T., Muthurajan H., Sikder A.K., Gandhe B.R., Rao A.S.
Journal of Hazardous Materials, 2009
159.
Refrigerants – Environmental Properties, The Engineering ToolBox, https://www.engineeringtoolbox.com/Refrigerants-Environment-Properties-d_1220.html (accessed 15 August 2021).
160.
1,1,1,2-Tetrafluoroethane, Concise International Chemical Assessment, World Health Organization, Geneva, 1998, Document 11.
161.
Human Safety and Pharmacokinetics of the CFC Alternative Propellants HFC 134a (1,1,1,2-Tetrafluoroethane) and HFC 227 (1,1,1,2,3,3,3-Heptafluoropropane) Following Whole-Body Exposure
Emmen H.H., Hoogendijk E.M., Klöpping-Ketelaars W.A., Muijser H., Duistermaat E., Ravensberg J.C., Alexander D.J., Borkhataria D., Rusch G.M., Schmit B.
Regulatory Toxicology and Pharmacology, 2000
162.
Safe and Convenient Synthesis of Primary N-Nitramines in the Freon Media
Zlotin S., Zharkov M., Kuchurov I., Fomenkov I., Tartakovsky V., Fedyanin I.
Synthesis, 2016
163.
Sustainable Synthesis of Polynitroesters in the Freon Medium and their in Vitro Evaluation as Potential Nitric Oxide Donors
Kuchurov I.V., Arabadzhi S.S., Zharkov M.N., Fershtat L.L., Zlotin S.G.
ACS Sustainable Chemistry and Engineering, 2018
165.
Continuous nitration of alcohols in a Freon flow
Zharkov M.N., Arabadzhi S.S., Kuchurov I.V., Zlotin S.G.
Reaction Chemistry and Engineering, 2019
166.
Fabrication and characterization of HMX@TPEE energetic microspheres with reduced sensitivity and superior toughness properties
Li Y., Yang Z., Zhang J., Pan L., Ding L., Tian X., Zheng X., Gong F.
Composites Science and Technology, 2017
169.
HMX surface modification with polymers via sc-CO2 antisolvent process: A way to safe and easy-to-handle energetic materials
Kosareva E.K., Zharkov M.N., Meerov D.B., Gainutdinov R.V., Fomenkov I.V., Zlotin S.G., Pivkina A.N., Kuchurov I.V., Muravyev N.V.
Chemical Engineering Journal, 2022
170.
Solution-mediated polymorphic transformation of CL-20: An approach to prepare purified form ε particles
Pan B., Wei H., Jiang J., Zong S., Lv P., Dang L.
Journal of Molecular Liquids, 2018
171.
Probing Crystal Growth of ε- and α-CL-20 Polymorphs via Metastable Phase Transition Using Microscopy and Vibrational Spectroscopy
Ghosh M., Venkatesan V., Mandave S., Banerjee S., Sikder N., Sikder A.K., Bhattacharya B.
Crystal Growth and Design, 2014
172.
Comparative Investigation of Thermal Decomposition of Various Modifications of Hexanitrohexaazaisowurtzitane (CL-20)
Nedelko V.V., Chukanov N.V., Raevskii A.V., Korsounskii B.L., Larikova T.S., Kolesova O.I., Volk F.
Propellants, Explosives, Pyrotechnics, 2000
174.
Micronization of CL-20 using supercritical and liquefied gases
Zharkov M.N., Kuchurov I.V., Zlotin S.G.
CrystEngComm, 2020
175.
Supercritical Antisolvent Processing of Nitrocellulose: Downscaling to Nanosize, Reducing Friction Sensitivity and Introducing Burning Rate Catalyst
Dobrynin O., Zharkov M., Kuchurov I., Fomenkov I., Zlotin S., Monogarov K., Meerov D., Pivkina A., Muravyev N.
Nanomaterials, 2019
176.
C. D. Cox and T. Liggett, US Patent 3671515A, 1970.
178.
10.1016/j.mencom.2021.11.001_b0890
Svec
Angew. Chem., Int. Ed., 1857
179.
Nitration of aromatics with dinitrogen pentoxide in a liquefied 1,1,1,2-tetrafluoroethane medium
Kharchenko A.K., Fauziev R.V., Zharkov M.N., Kuchurov I.V., Zlotin S.G.
RSC Advances, 2021