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E-raamat: Energetic Nanomaterials: Synthesis, Characterization, and Application

Edited by (Institute of Chemical Kinetics and Combustion, Siberian Branch, Academy of Sciences, Novosibirsk, Russia), Edited by (Process Engineering Faculty, Nuremberg Technical University Georg Simon Ohm, Nuremberg, Germany)
  • Formaat: PDF+DRM
  • Ilmumisaeg: 21-Jan-2016
  • Kirjastus: Elsevier Science Publishing Co Inc
  • Keel: eng
  • ISBN-13: 9780128027158
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Energetic Nanomaterials: Synthesis, Characterization, and ApplicationSuurem pilt
  • Formaat: PDF+DRM
  • Ilmumisaeg: 21-Jan-2016
  • Kirjastus: Elsevier Science Publishing Co Inc
  • Keel: eng
  • ISBN-13: 9780128027158
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Energetic Nanomaterials: Synthesis, Characterization, and Application provides researchers in academia and industry the most novel and meaningful knowledge on nEM, covering the fundamental chemical aspects from synthesis to application.

This valuable resource fills the current gap in book publications on nanoenergetics, the energetic nanomaterials that are applied in explosives, gun and rocket propellants, and pyrotechnic devices, which are expected to yield enhanced properties, such as a lower vulnerability towards shock initiation, enhanced blast, enhanced shelf-life, and environmentally friendly replacements of currently used materials.

The current lack of a systematic and easily available book in this field has resulted in an underestimation of the input of nanoEM to modern technologies. This book is an indispensable resource for researchers in academia, industry, and research institutes dealing with the production and characterization of energetic materials all over the world.

  • Written by high-level experts in the field of nanoenergetics
  • Covers the hot topic of energetic nanomaterials, including nanometals and their applications in nanoexplosives
  • Fills a gap in energetic nanomaterials book publications

Muu info

Fills the current gap in book publications on nanoenergetics, the energetic nanomaterials that are applied in explosives, gun and rocket propellants, and pyrotechnic devices, covering their unique properties and future applications
List of Contributors
xi
Preface xv
1 Nanoenergetic Materials: A New Era in Combustion and Propulsion
1(20)
Vladimir E. Zarko
1 Introduction
1(3)
2 Combustion of Al Nanoparticles
4(3)
3 Combustion of Nanothermite Compositions
7(3)
4 Combustion of Nanoexplosives
10(3)
5 Experimental Methods to Characterize Nanoenergetic Systems Performance
13(2)
6 Conclusion
15(6)
Acknowledgments
17(1)
References
17(4)
2 Fast-Reacting Nanocomposite Energetic Materials: Synthesis and Combustion Characterization
21(26)
Keerti Kappagantula
Michelle Pantoya
1 Introduction
21(6)
2 Effect of Fuel and Oxidizer Proximity on Combustion
27(6)
3 Tuning Combustion Performance of Energetic Nanocomposites Through Surface Functionalization of the Fuels
33(8)
4 Conclusions
41(6)
References
43(4)
3 Nanometals: Synthesis and Application in Energetic Systems
47(18)
Alexander A. Gromov
Alexander G. Korotkikh
A. Il'in
Luigi T. DeLuca
Vladimir A. Arkhipov
Konstantin A. Monogarov
Ulrich Teipel
1 Introduction
47(1)
2 Nanometals In Energetic Systems
48(5)
3 Ignition of Energetic Systems Containing Nanoaluminum
53(5)
4 Nanoaluminum Combustion in Solid Propellants
58(1)
5 Nanoaluminum Usage in Thermites
59(1)
6 Nanoaluminum in Explosives
60(1)
7 Conclusion
60(5)
Acknowledgment
60(1)
References
60(5)
4 Mechanisms and Microphysics of Energy Release Pathways in Nanoenergetic Materials
65(30)
M.R. Zachariah
G.C. Egan
1 Introduction
65(3)
2 Heat Transfer
68(4)
3 Physical Response of the Oxide Shell
72(5)
4 Reaction Mechanisms
77(12)
5 Conclusion and Future Directions
89(6)
References
91(4)
5 Applications of Nanocatalysts in Solid Rocket Propellants
95(26)
Feng-Sheng Li
Wei Jiang
Jie Liu
Xiao-de Guo
Yu-Jiao Wang
Ga-Zi Hao
1 Introduction
95(1)
2 Impact of Nanocatalysts on the Thermal Decomposition of Ammonium Perchlorate as Oxidizer in Solid Propellants
96(1)
3 Impact of Metal Nanoparticles on the Thermal Decomposition of AP
97(7)
4 Impact of Metallic Oxide Nanoparticles on the Thermal Decomposition of AP
104(2)
5 Impact of Hydrogen Storage Nanoparticles on the Thermal Decomposition of AP
106(3)
6 Impact of Nanocatalysts on the Thermal Decomposition of AP/HTPB Propellant
109(1)
7 Impact of Metal Nanoparticles on the Thermal Decomposition of AP/HTPB
110(3)
8 Impact of Hydrogen-Storage Nanoparticles on the Thermal Decomposition of AP/HTPB
113(3)
9 Impact of Nanocatalysts on the Combustion Performance of AP/HTPB Propellant
116(2)
10 Conclusions
118(3)
References
119(2)
6 Nanocoating for Activation of Energetic Metals
121(18)
Valery Rosenband
Alon Gany
1 Introduction
121(1)
2 Nickel-Coated Aluminum Particles
122(3)
3 Thormoanalytical Tests
125(2)
4 Ignition Tests
127(7)
5 Iron-Coated Aluminum Particles
134(2)
6 Conclusions
136(3)
References
137(2)
7 Nanostructured Energetic Materials and Energetic Chips
139(24)
Ruiqi Shen
Yinghua Ye
Peng Zhu
Yan Hu
Lizhi Wu
Zhao Qin
1 Introduction
139(1)
2 1D NSEMs and Energetic Chips
139(9)
3 Two Dimensional NSEMs and Energetic Chips
148(8)
4 Three Dimensional NSEMs and Energetic Chips
156(5)
5 Conclusions
161(2)
Acknowledgments
161(1)
References
161(2)
8 Combustion Behavior of Nanocomposite Energetic Materials
163(30)
Alexander S. Mukasyan
Alexander S. Rogachev
1 Introduction
163(1)
2 Nanostructured Composite High-Energy-Density Materials
164(9)
3 Nanothermites
173(14)
4 Conclusions
187(6)
Acknowledgments
188(1)
References
188(5)
9 Catalysis of HMX Decomposition and Combustion: Defect Chemistry Approach
193(38)
Alia N. Pivkina
Nikita V. Muravyev
Konstantin A. Monogarov
Igor V. Fomenkov
J. Schoonman
1 Introduction
193(3)
2 Experimental
196(5)
3 Results and Discussion
201(16)
4 Elaboration of the Physicochemical Model of Catalytic Influence of Nano-TiO2 on HMX Thermolysis
217(9)
5 Summary
226(5)
Acknowledgment
227(1)
References
227(4)
10 Preparation, Characterization, and Catalytic Activity of Carbon Nanotubes-Supported Metal or Metal Oxide
231(54)
Feng-Qi Zhao
Jian-Hua Yi
Wei-Liang Hong
Ting An
Yan-Jing Yang
1 Introduction
231(1)
2 Preparation and Characterization
232(34)
3 Catalytic Activity of CNTs-Supported Catalysts in Thermal Decomposition of Energetic Materials
266(12)
4 Application in Solid Rocket Propellants
278(4)
5 Conclusions
282(3)
References
283(2)
11 Formation of Nanosized Products in Combustion of Metal Particles
285(38)
Oleg G. Glotov
Vladimir E. Zarko
1 Introduction
285(5)
2 Experimental Techniques for Particle Sampling
290(6)
3 Original Experimental Approaches
296(4)
4 Characteristics of Oxide Nanoparticles
300(15)
5 Conclusions and Future Work
315(8)
Acknowledgments
316(1)
References
316(7)
12 Encapsulated Nanoscale Particles and Inclusions in Solid Propellant Ingredients
323(18)
S.F. Son
B.C. Terry
S. Isert
T.R. Sippel
I.E. Gunduz
L.J. Groven
1 Encapsulated Nanoscale Catalysts
323(5)
2 Engineered Metallic Fuels and Alloys
328(2)
3 Composites of Nanoscale Aluminum Particles
330(1)
4 Micrometer-Sized Aluminum Particles with Inclusions
331(4)
5 Microexploding Alloy Fuel Particles
335(3)
6 Conclusions
338(3)
Acknowledgments
339(1)
References
339(2)
13 Pre-burning Characterization of Nanosized Aluminum in Condensed Energetic Systems
341(28)
Christian Paravan
Filippo Maggi
Stefano Dossi
Gianluigi Marra
Giovanni Colombo
Luciano Galfetti
Nomenclature
341(1)
Chemicals Common Names and IUPAC Nomenclature
342(1)
1 Introduction
342(5)
2 Tested Aluminum Powders: Production, Passivation, and Coating
347(2)
3 Morphology, Structure, and Metal Content of Nanosized Aluminum Powders
349(3)
4 Nanosized AI Powder Reactivity
352(4)
5 Rheology of Nanosized Aluminum-Loaded Solid Fuels and Propellant Slurries
356(7)
6 Conclusion and Future Development
363(6)
Acknowledgments
365(1)
References
366(3)
Index 369
Prof. Dr. Vladimir E. Zarko is Head of the Condensed Systems Combustions Laboratory of the Institute of Chemical Kinetics and Combustion, the Siberian Branch of the Russian Academy of Sciences. He graduated from Tomsk State University and obtained a PhD in 1971 and a DSc in 1985 from the Institute of Hydrodynamics, Russian Academy of Sciences, Novosibirsk. He became a professor at Novosibirsk Technical Institute in 1989. His scientific activity has focused on the processes of ignition and transient combustion of the condensed systems. Results of his research have been generalized in the monograph Ignition of Solids, co-authored with Prof. V.N. Vilyunov, Elsevier, 1989. He has since published several books and more than 170 papers in peer reviewed journals, and he has been issued 11 patents. He has served as Associate Editor of the journal Combustion, Explosion, and Shock Waves in Novosibirsk for many years, and he serves on the advisory board of two international journals. Since 2000 he has served as President of the Novosibirsk Division of the Russian Federation of Cosmonautics. Prof. Zarko has traveled to institutions all over the world as a researcher and lecturer. At present his scientific interests are focused on energetic nanomaterials and initiation of high explosives by laser and electron beam pulsed irradiation. Prof. Alexander Gromov is currently working at the Process Engineering Faculty, Nuremberg Technical University Georg Simon Ohm, Nuremberg, Germany. He obtained his academic degrees from Bijsk Technologic Institute (1998, Chem.Eng.) and Tomsk Polytechnic University (2000, PhD). Since 2001 he has worked at Tomsk Polytechnic University (Russia), University of Ulsan (South Korea), and Forschungszentrum Karlsruhe and Fraunhofer Institute of Chemical Technology (Germany). He was a visiting professor at the Aerospace Engineering Department of Milan Polytechnic University in 2011-2013 before obtaining the Humboldt Grant for Experienced Researchers and moving to Nuremberg Technical University George Simon Ohm in 2013. Prof. Gromov has authored over 100 scientific publications and several books and has received numerous scientific awards, including the Russian Academy of Science Medal in 2009. He is also a member of the European Committee of the "Global Energy Prize."
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