nr |
titel |
auteur |
tijdschrift |
jaar |
jaarg. |
afl. |
pagina('s) |
type |
1 |
Adsorptivity of Some Organic Compounds to Copper Nanoparticles
|
Shafigulin, R. V. |
|
|
|
1 |
p. 47-50 |
artikel |
2 |
Advanced methods for SHS of powders developed in Krakow
|
Pampuch, R. |
|
2008 |
|
1 |
p. 85-91 |
artikel |
3 |
Aluminothermic SHS of ferrochromium from ore concentrate: Influence of Al content of green composition on phase segregation
|
Kachin, A. R. |
|
2016 |
|
1 |
p. 59-61 |
artikel |
4 |
Behavior of the Ti-Al system during mechanical activation
|
Kovalev, D. Yu. |
|
2013 |
|
1 |
p. 56-59 |
artikel |
5 |
Calciothermic reduction of titanium dioxide and molybdenum trioxide under pressure of nitrogen gas
|
Avramchik, A. N. |
|
2017 |
|
1 |
p. 80-82 |
artikel |
6 |
Call for papers
|
|
|
2011 |
|
1 |
p. 65 |
artikel |
7 |
Call for papers
|
|
|
2009 |
|
1 |
p. 68 |
artikel |
8 |
Capillary Spreading of Copper Melt over SHS-Produced NiAl
|
Gabbasov, R. M. |
|
|
|
1 |
p. 52-54 |
artikel |
9 |
Carbon combustion synthesis of nanostructured perovskites
|
Martirosyan, K. S. |
|
|
|
1 |
p. 36-45 |
artikel |
10 |
Carbon combustion synthesis of nanostructured perovskites
|
Martirosyan, K. S. |
|
2007 |
|
1 |
p. 36-45 |
artikel |
11 |
Carbon combustion synthesis of oxides: Effect of Mach, Peclet, and Reynolds numbers on gas dynamics
|
Markov, A. A. |
|
2013 |
|
1 |
p. 11-17 |
artikel |
12 |
Cast ceramics by metallothermic SHS under elevated argon pressure
|
Gorshkov, V. A. |
|
2017 |
|
1 |
p. 60-64 |
artikel |
13 |
Catalyst Based on Mesoporous Silica Gel Doped with Terbium and Modified with Nickel Obtained by High-Temperature Template Method for Aromatic Hydrocarbons Hydrogenation
|
Tokranov, A. A. |
|
|
|
1 |
p. 49-57 |
artikel |
14 |
Catalytic Activity of KOH–CaO–Al2O3 Nanocomposites in Biodiesel Production: Impact of Preparation Method
|
Nayebzadeh, H. |
|
2019 |
|
1 |
p. 18-27 |
artikel |
15 |
Cellular Infiltration Combustion of Ti Powder in Planar Ducts in Conditions of Restricted Air Access
|
Krishenik, P. M. |
|
2019 |
|
1 |
p. 68-70 |
artikel |
16 |
Cermet-lined tubes from industrial wastes by centrifugal SHS
|
Andreev, D. E. |
|
2011 |
|
1 |
p. 27-32 |
artikel |
17 |
Combined Use of SHS and SPS: Important Mechanistic Details
|
Rogachev, A. S. |
|
|
|
1 |
p. 22-29 |
artikel |
18 |
Combustion of Cr2O3 + Al powder mixtures in a coflow of inert gas: 5. Effect of green density
|
Seplyarskii, B. S. |
|
2009 |
|
1 |
p. 42-45 |
artikel |
19 |
Combustion of Granulated Gasless Mixtures in a Flow of Inert Gas
|
Lapshin, O. V. |
|
2018 |
|
1 |
p. 14-17 |
artikel |
20 |
Combustion of granulated 5Ti + 3Si mixtures in a coflow of nitrogen gas: Some mechanistic aspects
|
Tarasov, A. G. |
|
2015 |
|
1 |
p. 38-41 |
artikel |
21 |
Combustion of Si–C Mixtures in Nitrogen Gas: Impact of Iron-Containing Additives
|
Barinova, T. V. |
|
2019 |
|
1 |
p. 39-44 |
artikel |
22 |
Combustion of silicon powders containing organic additives in nitrogen gas under pressure: 2. Composition of combustion products
|
Barinova, T. V. |
|
2009 |
|
1 |
p. 30-33 |
artikel |
23 |
Combustion of silicon powders containing organic additives in nitrogen gas under pressure: 1. Effect of dopants on combustion phenomenology
|
Barinova, T. V. |
|
2009 |
|
1 |
p. 25-29 |
artikel |
24 |
Combustion of the Fe-Si alloy in nitrogen gas
|
Chukhlomina, L. N. |
|
|
|
1 |
p. 18-22 |
artikel |
25 |
Combustion of the Fe-Si alloy in nitrogen gas
|
Chukhlomina, L. N. |
|
2007 |
|
1 |
p. 18-22 |
artikel |
26 |
Combustion of Thermite TiO2/ZrO2–Ca Mixtures in Nitrogen Gas
|
Maksimov, Yu. M. |
|
|
|
1 |
p. 31-35 |
artikel |
27 |
Combustion of Ti–Al–C compacts in air and helium: A TRXRD study
|
Bazhin, P. M. |
|
2016 |
|
1 |
p. 30-34 |
artikel |
28 |
Combustion of Ti–Al Mixtures: Influence of Preheating, Mechanical Activation, and Burning Mode
|
Kochetov, N. A. |
|
|
|
1 |
p. 26-30 |
artikel |
29 |
Combustion of Ti–C Powders and Granules: Impact of Carbon Allotropy and Ti Particle Size
|
Seplyarskii, B. S. |
|
|
|
1 |
p. 54-56 |
artikel |
30 |
Combustion synthesis and structural characterization of YAG: Influence of fuel and Si doping
|
Upasani, M. |
|
2017 |
|
1 |
p. 22-32 |
artikel |
31 |
Combustion synthesis of borate phosphors for use in plasma display panels and mercury-free fluorescent lamps
|
Nagpure, P. A. |
|
2013 |
|
1 |
p. 32-36 |
artikel |
32 |
Combustion Synthesis of Cermets from Granular Mixtures Ti–C–NiCr for Protective Coatings
|
Seplyarskii, B. S. |
|
|
|
1 |
p. 80-86 |
artikel |
33 |
Combustion synthesis of complex carbohydrides in the Ti-Nb-W-C-H system
|
Aghajanyan, N. N. |
|
2012 |
|
1 |
p. 7-10 |
artikel |
34 |
Combustion Synthesis of Eutectic TiB2/TiN Alloy
|
Tarasov, A. G. |
|
2019 |
|
1 |
p. 74-76 |
artikel |
35 |
Combustion synthesis of heterogeneous calcium phosphate bioceramics from calcium oxide and phosphate precursors
|
Ayers, R. |
|
2011 |
|
1 |
p. 6-14 |
artikel |
36 |
Combustion synthesis of Mo5Si3 in chemical furnace
|
Gao, J. -Y. |
|
2008 |
|
1 |
p. 49-53 |
artikel |
37 |
Combustion synthesis of multicomponent ceramic phosphors for solid state lighting
|
Yadav, P. J. |
|
2012 |
|
1 |
p. 32-37 |
artikel |
38 |
Combustion synthesis of nickel-ferrite magnetic materials
|
Chanadee, T. |
|
2017 |
|
1 |
p. 40-43 |
artikel |
39 |
Combustion synthesis of PZN-10PT nanopowders
|
Raigoza, C. F. V. |
|
2012 |
|
1 |
p. 11-18 |
artikel |
40 |
Combustion synthesis of SOFC materials in a continuous reactor
|
Avakyan, P. B. |
|
2009 |
|
1 |
p. 1-6 |
artikel |
41 |
Combustion synthesis of some compounds in the Li2O-Al2O3 system
|
Kale, M. A. |
|
2012 |
|
1 |
p. 19-24 |
artikel |
42 |
Combustion Synthesis of TiC Powders from Ilmenite Mineral and Activated Carbon
|
Rattanaphan, N. |
|
|
|
1 |
p. 51-54 |
artikel |
43 |
Combustion Wave Propagation in between Two Reactive Layers: Mathematical Modeling with Account for Melting and Interdiffusion
|
Shkadinsky, K. G. |
|
|
|
1 |
p. 5-10 |
artikel |
44 |
Composite Catalyst for Conversion of Plastic Waste to Fuel: Preparation and Performance
|
Abdelrahman, A. |
|
|
|
1 |
p. 10-16 |
artikel |
45 |
Concentration Limits for Wave Propagation in Powdered and Granulated (Ti + C) + хAl2O3 Mixtures
|
Seplyarskii, B. S. |
|
2018 |
|
1 |
p. 66-68 |
artikel |
46 |
Coupled SHS Reactions as a useful tool for synthesis of materials: An overview
|
Kharatyan, S. L. |
|
2012 |
|
1 |
p. 59-73 |
artikel |
47 |
Current-Assisted Sintering of Combustion-Synthesized β-SiAlON Ceramics
|
Smirnov, K. L. |
|
2019 |
|
1 |
p. 28-33 |
artikel |
48 |
Cu–Sb Solder Alloy by Combustion Synthesis: Structural Characterization and Magnetic Properties
|
Hamdi, S. |
|
|
|
1 |
p. 30-35 |
artikel |
49 |
Cu-TiO2 composite as fabricated by SHS method
|
Javaherian, Sh. Sh. |
|
2014 |
|
1 |
p. 47-54 |
artikel |
50 |
Dispersion Strengthened Mo-Based Cast Composite by Centrifugal SHS
|
Vdovin, Yu. S. |
|
|
|
1 |
p. 49-51 |
artikel |
51 |
Dynamics in a rod model of solid flame waves revisited
|
Park, J. H. |
|
2008 |
|
1 |
p. 1-19 |
artikel |
52 |
Effect of batch pelletizing on a course of SHS reactions: An overview
|
Amosov, A. P. |
|
2010 |
|
1 |
p. 70-77 |
artikel |
53 |
Effect of Debye screening length on the electric voltage self-generated during nitridation of a metal particle
|
Filimonov, I. A. |
|
2010 |
|
1 |
p. 1-8 |
artikel |
54 |
Effect of Gamma Irradiation on Rare Earth Doped Nanocrystalline CaF2
|
Venkata Reddy, G. N. |
|
|
|
1 |
p. 37-41 |
artikel |
55 |
Effect of hydrogen on the structure of alloys formed in the Ti-Zr-Hf-H system
|
Shekhtman, V. Sh. |
|
2010 |
|
1 |
p. 40-48 |
artikel |
56 |
Effect of nitrogen to niobium atomic ratio on superconducting transition temperature of δ-NbNx powders
|
Linde, A. V. |
|
2010 |
|
1 |
p. 9-16 |
artikel |
57 |
Electrochemical features of combustion-synthesized lithium cobaltate as cathode material for lithium ion battery
|
Mamyrbaeva, Y. Y. |
|
2014 |
|
1 |
p. 1-8 |
artikel |
58 |
Electrothermal explosion under pressure: Ti–C blends in porous electroconducting envelope
|
Shcherbakov, V. A. |
|
2016 |
|
1 |
p. 39-42 |
artikel |
59 |
Fast densification of nanocrystalline yttria ceramics without grain growth
|
Li, B. |
|
2015 |
|
1 |
p. 14-20 |
artikel |
60 |
Fine Ti Powders Through Metallothermic Reduction in TiO2–Mg–Ca Mixtures
|
Vershinnikov, V. I. |
|
2018 |
|
1 |
p. 55-59 |
artikel |
61 |
Fingering in coflow filtration combustion: Influence of ignition conditions
|
Aldushin, A. P. |
|
2015 |
|
1 |
p. 1-7 |
artikel |
62 |
Formation of triple alloys and their hydrides in the Ti-Zr-Hf-H system
|
Aleksanyan, A. G. |
|
2010 |
|
1 |
p. 34-39 |
artikel |
63 |
FTIR spectra and elastic properties of Cd-substituted Ni–Zn ferrites
|
Patil, M. R. |
|
2017 |
|
1 |
p. 33-39 |
artikel |
64 |
Gasless combustion in two-layer structures: A theoretical model
|
Prokof’ev, V. G. |
|
2013 |
|
1 |
p. 5-10 |
artikel |
65 |
Gas Release during Combustion of W–Teflon–Al Mixtures
|
Vadchenko, S. G. |
|
2019 |
|
1 |
p. 64-67 |
artikel |
66 |
Generation of electric signals during combustion of heterogeneous condensed systems
|
Kuznetsov, M. V. |
|
2009 |
|
1 |
p. 66-67 |
artikel |
67 |
Generation of Thermo-EMF during Combustion of Ti–хB Mixtures (x = 0.75–5.5) in Conditions of Quasi-Static Compression
|
Shcherbakov, V. A. |
|
|
|
1 |
p. 47-50 |
artikel |
68 |
HEA-Matrix TiB2 Composites by SHS Method
|
Kochetov, N. A. |
|
|
|
1 |
p. 24-30 |
artikel |
69 |
Hexachloroethane as an efficient oxidizer in combustion synthesis of carbonaceous and ceramic nanostructures
|
Szala, M. |
|
2010 |
|
1 |
p. 28-33 |
artikel |
70 |
High thermal conductivity ceramics from combustion synthesized AlN powder through microwave sintering and reheating
|
Chung, S. L. |
|
2012 |
|
1 |
p. 45-50 |
artikel |
71 |
Historical perspective and contribution of US researchers into the field of self-propagating high-temperature synthesis (SHS)/combustion synthesis (CS): Personal reflections
|
McCauley, J. W. |
|
2008 |
|
1 |
p. 58-75 |
artikel |
72 |
Hydrogenation of Xylenes, Ethylbenzene, and Isopropylbenzene on Ni Nanoparticles
|
Shafigulin, R. V. |
|
|
|
1 |
p. 42-46 |
artikel |
73 |
III French-Russian workshop on SHS and reactive nanosystems Université de Bourgogne, Dijon, October 2–6, 2010
|
|
|
2011 |
|
1 |
p. 64 |
artikel |
74 |
Impact of Magnesium on Structural and Morphological Study of Co–Zn Ferrites
|
Kolekar, R. Y. |
|
|
|
1 |
p. 58-66 |
artikel |
75 |
Infiltration-mediated combustion in porous media: Propagation of cellular structures in conditions of heat losses
|
Kostin, S. V. |
|
2017 |
|
1 |
p. 6-10 |
artikel |
76 |
Influence of granulation on combustion of 2Ti + C mixtures
|
Seplyarskii, B. S. |
|
2013 |
|
1 |
p. 65-67 |
artikel |
77 |
Influence of high-energy ball milling on reaction kinetics in the Ni-Al system: An electrothermorgaphic study
|
Nepapushev, A. A. |
|
2015 |
|
1 |
p. 21-28 |
artikel |
78 |
Influence of Mechanochemical Activation on the Combustion Parameters and Phase Composition of ZnO–Co3O4–Mg(NO3)2·6H2O–Al2O3–Al Pigments
|
L’vov, O. V. |
|
|
|
1 |
p. 8-14 |
artikel |
79 |
Influence of Starting Reagents on the Formation of Ti3SiC2 Porous Skeleton by SHS in Air
|
Davydov, D. M. |
|
|
|
1 |
p. 26-32 |
artikel |
80 |
Initiation of SHS reactions with concentrated solar radiation
|
Lytvynenko, Yu. M. |
|
2015 |
|
1 |
p. 47-48 |
artikel |
81 |
In-situ formation of cast granules in thermit-type SHS reactions
|
Ikornikov, D. M. |
|
2011 |
|
1 |
p. 15-19 |
artikel |
82 |
Interaction of Cu Melt with Graphite Fibers
|
Sytschev, A. E. |
|
|
|
1 |
p. 51-53 |
artikel |
83 |
Interaction of transition metals and alloys with hydrogen in conventional SHS and radiation-assisted thermal explosion modes
|
Dolukhanyan, S. K. |
|
2008 |
|
1 |
p. 30-40 |
artikel |
84 |
Intermetallic WSi2–W5Si3 Alloy by Magnesiothermic SHS Reaction
|
Maung, S. T. M. |
|
2019 |
|
1 |
p. 50-55 |
artikel |
85 |
Iron-Containing Pigments by SHS Method
|
Radishevskaya, N. I. |
|
|
|
1 |
p. 55-57 |
artikel |
86 |
Lightweight Al–Ti–Mg Alloy by SHS Method
|
Lazarev, P. A. |
|
|
|
1 |
p. 55-57 |
artikel |
87 |
Load-assisted SHS joining of NiAl to Ni
|
Sytschev, A. E. |
|
2013 |
|
1 |
p. 52-55 |
artikel |
88 |
Low-temperature solution-combustion synthesis and magneto-structural characterization of polycrystalline La1–xAgyMnO3 (y ≤ x) manganites
|
Ehi-Eromosele, C. O. |
|
2016 |
|
1 |
p. 23-29 |
artikel |
89 |
Macroscopic theory of mechanochemical synthesis in heterogeneous systems
|
Smolyakov, V. K. |
|
|
|
1 |
p. 1-11 |
artikel |
90 |
Macroscopic theory of mechanochemical synthesis in heterogeneous systems
|
Smolyakov, V. K. |
|
2007 |
|
1 |
p. 1-11 |
artikel |
91 |
Mathematical formalism to the theory of multiple (reiterated) self-propagating high-temperature synthesis
|
Lapshin, O. V. |
|
2016 |
|
1 |
p. 1-4 |
artikel |
92 |
Mechanically activated aluminothermic reduction of titanium dioxide
|
Kamali, A. R. |
|
2009 |
|
1 |
p. 7-10 |
artikel |
93 |
Mechanically activated SHS of NiAl: Effect of Ni morphology and mechanoactivation conditions
|
Kochetov, N. A. |
|
2012 |
|
1 |
p. 55-58 |
artikel |
94 |
Mechanically induced self-sustaining reactions
|
Ebrahimi-Kahrizsangi, R. |
|
2016 |
|
1 |
p. 5-13 |
artikel |
95 |
Mechanoactivated SHS in Ferrotitanium–Carbon Black Powder Mixtures
|
Pribytkov, G. A. |
|
|
|
1 |
p. 61-63 |
artikel |
96 |
Mechanoactivation of Ni-Al blends in a ball mill: Influence of ball/mill ratio
|
Kochetov, N. A. |
|
2015 |
|
1 |
p. 29-32 |
artikel |
97 |
Mechanoactivation of SHS systems and processes
|
Levashov, E. A. |
|
|
|
1 |
p. 46-50 |
artikel |
98 |
Mechanoactivation of SHS systems and processes
|
Levashov, E. A. |
|
2007 |
|
1 |
p. 46-50 |
artikel |
99 |
Mechanochemical synthesis of nanosize products in heterogeneous systems: Macroscopic kinetics
|
Smolyakov, V. K. |
|
2008 |
|
1 |
p. 20-29 |
artikel |
100 |
Metal-Doped MgB2 by Thermal Explosion: A TRXRD Study
|
Potanin, A. Yu. |
|
2018 |
|
1 |
p. 18-25 |
artikel |
101 |
Metallurgical SHS Processes as a Route to Industrial-Scale Implementation: An Autoreview
|
Ziatdinov, M. Kh. |
|
2018 |
|
1 |
p. 1-13 |
artikel |
102 |
Microwave-assisted combustion synthesis in mechanically activated 3Ti + Al powder mixtures: Structure formation issues
|
Filimonov, V. Yu. |
|
2014 |
|
1 |
p. 18-25 |
artikel |
103 |
Microwave ignited combustion synthesis as a joining technique for dissimilar materials: Modeling and experimental results
|
Colombini, E. |
|
2012 |
|
1 |
p. 25-31 |
artikel |
104 |
Mn–Zn Ferrite Nanoparticles by Calcining Amorphous Products of Solution Combustion Synthesis: Preparation and Magnetic Behavior
|
Martinson, K. D. |
|
|
|
1 |
p. 17-23 |
artikel |
105 |
Multilayer polymer structures containing Ni/Cu nanoclusters as prepared by selective laser sintering
|
Shishkovsky, I. V. |
|
2011 |
|
1 |
p. 53-60 |
artikel |
106 |
Nanocomposites mAl2O3–nYSZ by Impregnation Combustion Synthesis with Urea as a Fuel
|
Khaliullin, Sh. M. |
|
2019 |
|
1 |
p. 1-9 |
artikel |
107 |
Nanocrystalline Cobalt Ferrite Powders by Spray Solution Combustion Synthesis
|
Minin, R. V. |
|
|
|
1 |
p. 1-9 |
artikel |
108 |
Ni3Аl/C Composites by Thermal Explosion
|
Sytschev, A. E. |
|
2018 |
|
1 |
p. 64-65 |
artikel |
109 |
Nitride nanopowders by azide SHS technology
|
Amosov, A. P. |
|
2017 |
|
1 |
p. 11-21 |
artikel |
110 |
Non-chain autoacceleration of SHS wave in conditions of rotation
|
Ksandopulo, G. I. |
|
2015 |
|
1 |
p. 8-13 |
artikel |
111 |
Non-isothermal phenomena in Mo/Si diffusion couple: Reaction kinetics and structure formation
|
Kharatyan, S. L. |
|
2013 |
|
1 |
p. 18-26 |
artikel |
112 |
Novel approaches to solution-combustion synthesis of nanomaterials
|
Mukasyan, A. S. |
|
|
|
1 |
p. 23-35 |
artikel |
113 |
Novel approaches to solution-combustion synthesis of nanomaterials
|
Mukasyan, A. S. |
|
2007 |
|
1 |
p. 23-35 |
artikel |
114 |
Novel combustion synthesis of La3+-substituted MnFe2O4
|
Berchmans, L. J. |
|
2009 |
|
1 |
p. 11-14 |
artikel |
115 |
One-step combustion synthesis of Tb3Al5O12:Ce phosphor
|
Yadav, P. J. |
|
2014 |
|
1 |
p. 41-46 |
artikel |
116 |
ORR Catalysts Based on Carbon Nanotubes and Metal Phthalocyanines Obtained by High-Temperature Synthesis
|
Shafigulin, R. V. |
|
|
|
1 |
p. 39-48 |
artikel |
117 |
Oxynitrides by aluminothermic SHS in nitrogen gas: Influence of nitrogen pressure
|
Silyakov, S. L. |
|
2017 |
|
1 |
p. 71-74 |
artikel |
118 |
Patterns of Synthesis of TiC–NiCr Cermets from Powder Mixtures: Influence of Nichrome Content and Titanium Particles Size
|
Seplyarskii, B. S. |
|
|
|
1 |
p. 75-79 |
artikel |
119 |
Perovskite-type MgCNi3 superconductors as prepared by combined sintering-ETE process and SHS reaction: Structural and superconducting properties
|
Bendjemil, B. |
|
2010 |
|
1 |
p. 52-56 |
artikel |
120 |
Plasma-arc growth of refractory single crystals from SHS products and green mixtures: an autoreview
|
Ponomarev, M. A. |
|
2009 |
|
1 |
p. 51-59 |
artikel |
121 |
Preparation of CaF2:U phosphor by solid-state metathesis reaction
|
Pote, S. S. |
|
2013 |
|
1 |
p. 37-40 |
artikel |
122 |
Preparation of Green Mixtures for SHS Reactions: Characterization by Impedance Spectroscopy
|
Tsarev, M. V. |
|
|
|
1 |
p. 22-25 |
artikel |
123 |
Preparation of Ni3Al by Thermal Explosion under Pressure: Influence of Precompaction Pressure and Delay Time for Compaction Pressure
|
Boyangin, E. N. |
|
|
|
1 |
p. 15-21 |
artikel |
124 |
Preparation of Ti3AlC2–Al Cermets by Combined Use of SHS of Ti3AlC2 Porous Skeleton and Spontaneous Infiltration with Al and Al-Based Melts
|
Latukhin, E. I. |
|
|
|
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Preparation of Ti2AlN by reactive sintering
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Luginina, M. A. |
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2016 |
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p. 35-38 |
artikel |
126 |
Preparation of Ti3SiC2–Sn(Pb) Cermet by SHS of Ti3SiC2 Porous Skeleton with Subsequent Spontaneous Infiltration with Sn–Pb Melt
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Umerov, E. R. |
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p. 30-35 |
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127 |
Propagation of solid flame along a wire rolled in spiral
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Aldushin, A. P. |
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2017 |
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p. 1-5 |
artikel |
128 |
Rapidly Synthesizing Cu2Sb Phase of Tetragonal Structure by Electrothermal Explosion
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Hafs, A. |
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p. 67-74 |
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Reduction of Mn, Cr, and V Precursors in a Wave of Flameless RDX Combustion
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Mikhailov, Yu. M. |
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p. 11-14 |
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130 |
Rehabilitation/reanimation of oil wells by thermal shock
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Kobyakov, V. P. |
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2009 |
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p. 64-65 |
artikel |
131 |
Resistometry and impedance spectroscopy for characterization of powders used in SHS reactions
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Mokrushin, V. V. |
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2014 |
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p. 26-35 |
artikel |
132 |
Self-ordering of balls in compressed thin layers
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Ponomarev, M. A. |
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2016 |
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p. 43-49 |
artikel |
133 |
Self-Propagating High-Temperature Synthesis of Complex Phases: The Example of TiC-Based Composites
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Ramdane, W. |
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p. 1-25 |
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134 |
Self-Propagating High-Temperature Synthesis of MgB2 superconductor: A Review
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Ramdane, W. |
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135 |
Self-Propagating High-Temperature Synthesis of Titanium Carbide: An Educational Module using a Wooden Block Reactor
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Warner, T. E. |
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2019 |
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p. 56-63 |
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136 |
Self-Purification from Impurities during SHS of titanium hydride
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Potekhin, A. A. |
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2014 |
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p. 58-61 |
artikel |
137 |
Shock-Induced Chemical Transformations in Ti–B–Ni and Ti–C–Ni Powder Blends
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Saikov, I. V. |
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p. 10-14 |
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138 |
SHS amidst other new processes for in-situ synthesis of Al-matrix composites: A review
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Nath, H. |
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2016 |
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p. 50-58 |
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139 |
SHS-based fabrication of inorganic materials with desired structure and porosity
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Boyarchenko, O. D. |
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2011 |
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p. 20-26 |
artikel |
140 |
SHS Casting of (Mo,W)Si2, (Mo,Nb)Si2, and (Mo,Ti)Si2 silicides: effect of activating 3CaO2 + 2Al additives
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Gorshkov, V. A. |
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2014 |
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p. 36-40 |
artikel |
141 |
SHS in a flow of inert gas: Effect of flow direction
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Brauer, G. B. |
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2014 |
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p. 62-64 |
artikel |
142 |
SHS in Italy: An overview
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Cao, G. |
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2008 |
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p. 76-84 |
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143 |
SHS in the Nb–Si system: Influence of mechanical alloying
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Shkoda, O. A. |
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2016 |
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p. 14-16 |
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144 |
SHS in the Si–xC–CO2 System (x = 0–30 wt %): Impact of Synthesis Conditions and Green Composition
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Barinova, T. V. |
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p. 6-9 |
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SHS in the Ternary System (Ni + Al) + xMg (х = 0–50 wt %)
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p. 31-36 |
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SHS joining by thermal explosion in (Ni + Al)/Nb/(Ni + Al + Nb) sandwiches: Microstructure of transition zone
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Sytschev, A. E. |
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2017 |
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p. 49-53 |
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147 |
SHS joining in the Ti–C–Si system
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Kamynina, O. K. |
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2016 |
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p. 62-65 |
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148 |
SHS joining in the Ti-Si-C system: Structure of transition layer
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Vadchenko, S. G. |
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2013 |
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p. 46-51 |
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149 |
SHS of boron carbide: Influence of combustion temperature
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Kovalev, I. D. |
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2015 |
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p. 33-37 |
artikel |
150 |
SHS of Highly Dispersed Si3N4–SiC Ceramic Composites from Si–NaN3–Na2SiF6–C Powder Mixture
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Belova, G. S. |
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p. 15-22 |
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SHS of metal-oxide systems in a DC magnetic field: Part 1. TRXRD and thermal imaging studies of the Fe-Fe2O3 system
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Sivasubramanaiam, R. |
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2011 |
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p. 40-47 |
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152 |
SHS of pyrochlore-type ceramic matrices for immobilization of actinide-containing nuclear wastes
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Barinova, T. V. |
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2017 |
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1 |
p. 54-59 |
artikel |
153 |
SHS of shape memory CuZnAl alloys
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Guerioune, M. |
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2008 |
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p. 41-48 |
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154 |
SHS of (Ti,Cr)C Powders with Ni-Containing Binder from Granulated Green Mixtures
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p. 42-45 |
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155 |
SHS of transition metal-oxide systems in a DC magnetic field: Part 2. TRXRD, thermal imaging, and chemomagnetic studies of metal-oxide systems
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Sivasubramanaiam, R. |
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2011 |
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p. 48-52 |
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156 |
SHS-produced Fe-(TiMo)C master alloy for reinforcement of manganese steel
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Agote, I. |
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2010 |
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p. 17-22 |
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157 |
SHS-produced intermetallides as catalysts for deep oxidation of carbon monoxide and hydrocarbons
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Pugacheva, E. V. |
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2010 |
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p. 65-69 |
artikel |
158 |
SHS-produced β-sialons as supports for oxidation catalysts
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Borshch, V. N. |
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2009 |
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p. 38-41 |
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159 |
SHS reaction and explosive crystallization in thin films: Resemblance and distinction
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Rogachev, A. S. |
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2017 |
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p. 44-48 |
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160 |
SHS reaction in Zn-S powder blends under quasi-isostatic pressure
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Barinov, V. Yu. |
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2013 |
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p. 27-31 |
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161 |
SHS reaction of Ti-Zr-Hf alloys with hydrogen
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Mayilyan, D. G. |
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2012 |
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p. 38-40 |
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162 |
SHS reactions in Ni-Al foils: A time-resolved XRD study
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Kochetov, N. A. |
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p. 55-57 |
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163 |
SHS under pressure: II. Effect of applied pressure on burning velocity in Ti + C mixtures
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Shcherbakov, V. A. |
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2011 |
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p. 36-39 |
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164 |
SHS under pressure: I. Thermal electromotive force arising during combustion of Ti + C mixtures
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Shcherbakov, V. A. |
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2011 |
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p. 33-35 |
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165 |
β-SiAlON–BN composites by infiltration-mediated SHS under high pressure of nitrogen gas
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Smirnov, K. L. |
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2016 |
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p. 17-22 |
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166 |
Single-phase NbSi2 by mechanoactivated SHS
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Shkoda, O. A. |
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2017 |
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p. 83-85 |
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167 |
Sintering of SHS-produced α-Si3N4, α-SiAlON, and β-SiAlON
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Loryan, V. E. |
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2012 |
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p. 41-44 |
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168 |
Solid Solution (AlN)x(SiC)1–x (x ≈ 0.7) by SHS under High Pressure of Nitrogen Gas
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Borovinskaya, I. P. |
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2018 |
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p. 33-36 |
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169 |
Solid-State Synthesis and Structural Features of Li0.5Ni0.75 – x/2Znx/2Fe2O4 Ferrites
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Durgadsimi, S. U. |
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2019 |
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p. 71-73 |
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170 |
Solution-combustion synthesis of nanosized iron oxide from ferric oxalate
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Barinova, T. V. |
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2012 |
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1 |
p. 1-6 |
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171 |
Spark plasma sintering of ZrB2- and HfB2-based Ultra High Temperature Ceramics prepared by SHS
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Licheri, R. |
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2009 |
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p. 15-24 |
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172 |
Stability of Stationary Filtration Combustion Front of Porous Metal Compounds
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Krishenik, P. M. |
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p. 1-7 |
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173 |
Structural Analysis of Nano Ferrites Synthesized by Combustion and Microwave Methods
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Molakeri, A. S. |
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2018 |
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p. 44-50 |
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174 |
Structural and Dielectric Properties of Lead-Free Zr-Doped Barium Titanates
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Vasawade, S. D. |
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2018 |
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p. 26-32 |
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175 |
Structural and mechanical properties of nanograined magnesium ferrite produced by oxalate coprecipitation method
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Shedam, R. M. |
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2017 |
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p. 75-79 |
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176 |
Structural and Optical Properties of (110) Plane Textured SnO2:Zn Thin Films
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Bannur, M. S. |
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2019 |
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p. 34-38 |
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177 |
Structure and Properties of SPS-produced Carbon-Containing NiAl
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Sytschev, A. E. |
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p. 58-60 |
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178 |
Subtle Details in Crystal Structure of SHS Products by DFT Calculations
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Konovalikhin, S. V. |
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p. 15-21 |
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179 |
Supported palladium catalysts prepared by surface self-propagating thermal synthesis
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Kotolevich, Y. S. |
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2014 |
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p. 9-17 |
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180 |
Supported Polymetallic Catalysts by Self-Propagating Surface Synthesis
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Borshch, V. N. |
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2019 |
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1 |
p. 45-49 |
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181 |
Synthesis and Ignition of Composite Ti–Cu Powders
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Vadchenko, S. G. |
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p. 46-48 |
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182 |
Synthesis and Structural Analysis of Co–Zn–Cd Ferrite by Williamson–Hall and Size–Strain Plot Methods
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Kulkarni, A. B. |
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2018 |
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p. 37-43 |
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183 |
Synthesis, Characterization, and Optical Properties of Y3Al5O12:Ce,Nd Phosphor by Mixed Fuel Combustion Synthesis
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Upasani, M. |
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p. 33-38 |
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184 |
Synthesis of boron carbide by calciothermic reduction process
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Berchmans, L. J. |
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2009 |
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p. 60-63 |
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185 |
Synthesis of fine boron nitride powders by combining direct boron nitridation with carbothermic boron oxide reduction
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Aghayan, M. |
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2009 |
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p. 46-50 |
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186 |
Synthesis of nanocrystalline boron nitride by combustion process
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Berchmans, L. J. |
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p. 34-37 |
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187 |
Synthesis of single-phase Ti-Al intermetallics
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Oniashvili, G. Sh. |
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p. 42-46 |
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188 |
Synthesis of γ-TiAl by thermal explosion + compaction route: Effect of process parameters and post-combustion treatment on product microstructure
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Lagos, M. A. |
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2010 |
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p. 23-27 |
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189 |
Ta4HfC5 Ceramic by Electro-Thermal Explosion under Pressure: Thermal and Electrical Parameters of the Process
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The effect of aluminum substitution on the mechanically induced self-sustaining reaction of molybdenum-silicon powders
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Takacs, L. |
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p. 41-45 |
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191 |
The Effect of Si Substitution for SiC on SHS in the Ti–Si–C System
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Tayebifard, S. A. |
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2018 |
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p. 51-54 |
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192 |
Theory of propagation limits for infiltration-mediated combustion in the absence of external gas supply
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Grachev, V. V. |
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p. 1-4 |
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193 |
Thermal Explosion in Nb–Si Mixtures: Influence of Mechanical Activation
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Shkoda, O. A. |
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2018 |
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p. 60-63 |
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194 |
Thermal explosion in various Ni-Al Systems: Effect of mechanical activation
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Vadchenko, S. G. |
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2013 |
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p. 60-64 |
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195 |
Thermally coupled SHS reactions
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Merzhanov, A. G. |
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2011 |
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p. 61-63 |
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196 |
Thermolysis of Calcium Iodate: Kinetic Parameters
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p. 40-46 |
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197 |
TiC–20% Cr(Ni) Composites by Forced SHS Compaction: Influence of Mechanical Activation Mode
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p. 58-59 |
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198 |
TiC–Fe Powders by Coupled SHS Reactions: An Overview
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Amosov, A. P. |
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2019 |
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p. 10-17 |
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199 |
(Ti0.8Cr0.2)B2–CrB–xTiN composites by pressure-assisted SHS
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Shcherbakov, V. A. |
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2017 |
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p. 65-70 |
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200 |
Time-resolved X-ray diffraction study of SHS-produced NiAl and NiAl-ZrO2 composites
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Tingaud, D. |
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p. 12-17 |
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201 |
Time-resolved X-ray diffraction study of SHS-produced NiAl and NiAl-ZrO2 composites
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Tingaud, D. |
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p. 12-17 |
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202 |
Titanium carbide by the SHS process ignited with aluminothermic reaction
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Benaldjia, A. |
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2008 |
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p. 54-57 |
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203 |
Ti–W Composite by Magnesiothermic SHS and Acid Leaching
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Ignat’eva, T. I. |
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p. 36-41 |
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204 |
To the Theory of Flow SHS Reactors
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Aldushin, A. P. |
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p. 1-4 |
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205 |
Ultra-Refractory Hf4ZrC5–(Hf,Zr)B2 Composites by Electrothermal Explosion under Pressure
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Shcherbakov, V. A. |
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p. 36-39 |
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206 |
Ultra-STEM-EELS characterization of MgB2 superconductor synthesized by different routes: Comparative study
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Bendjemil, B. |
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2010 |
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p. 57-64 |
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207 |
Uniaxial compression of Ti, B, and T-B powders: Structurization in case of spherical Ti particles
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Ponomarev, M. A. |
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2012 |
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p. 51-54 |
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208 |
WC-based catalyst for isopropyl alcohol dehydration as prepared by combustion synthesis
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Manukyan, Kh. V. |
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2011 |
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p. 1-5 |
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209 |
Welding in Ti–Al and Ni–Al Systems by Self-Propagating High-Temperature Synthesis
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Sytschev, A. E. |
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p. 36-40 |
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210 |
Zirconium intermetallides and their hydrides as obtained by hydride cycle route
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Hakobyan, H. G. |
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2010 |
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p. 49-51 |
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