nr |
titel |
auteur |
tijdschrift |
jaar |
jaarg. |
afl. |
pagina('s) |
type |
1 |
Advanced experimental facilities for SHS Studies and physico-chemical characterization of inorganic materials: An autoreview
|
Kuznetsov, M. V. |
|
2010 |
|
3 |
p. 191-205 |
artikel |
2 |
Aerosol Deposition of MAX Phase-Based Coatings onto High-Temperature Nickel Alloy
|
Manokhin, S. S. |
|
2019 |
|
3 |
p. 210-212 |
artikel |
3 |
Al-Doped Co-Cd Nanoferrites by Solution-Combustion Synthesis: Preparation and Structural Characterization
|
Shidaganal, L. C. |
|
|
|
3 |
p. 176-180 |
artikel |
4 |
Aluminothermic SHS of ferrotitanium from ilmenite: Influence of Al and KClO4 content of green composition
|
Azizov, Sh. T. |
|
2014 |
|
3 |
p. 161-164 |
artikel |
5 |
Aluminothermic SHS reactions: effect of scaling
|
Silyakov, S. L. |
|
2011 |
|
3 |
p. 176-180 |
artikel |
6 |
Aluminum nitride by microwave-assisted synthesis: Effect of added ammonium chloride
|
Angappan, S. |
|
2010 |
|
3 |
p. 214-220 |
artikel |
7 |
Aluminum oxynitride by SHS in chemical furnace
|
Borovinskaya, I. P. |
|
2015 |
|
3 |
p. 142-147 |
artikel |
8 |
Anisotropic ordered structures of silicon and silicon carbide by chemical vapor deposition
|
Rubtsov, N. M. |
|
2010 |
|
3 |
p. 186-190 |
artikel |
9 |
A process for production of titanium aluminide: Reaction mechanism
|
Kamali, A. R. |
|
2007 |
|
3 |
p. 119-124 |
artikel |
10 |
Bulk ultrahard composites in the eutectic TiB2-TiC system by SHS under high gravity
|
Zhao, Z. M. |
|
2009 |
|
3 |
p. 186-193 |
artikel |
11 |
Cast MoSiBTiC Composites by Metallothermic SHS: Influence of Ti and C Dopants
|
Yukhvid, V. I. |
|
|
|
3 |
p. 153-158 |
artikel |
12 |
Cermet membranes as catalyst supports for carbon-dioxide reforming of methane
|
Uvarov, V. I. |
|
2009 |
|
3 |
p. 217-218 |
artikel |
13 |
Cobalt-Doped Nickel Zinc Nanoferrites by Solution-Combustion Synthesis: Structural and Elastic Parameters
|
Shweta, G. M. |
|
|
|
3 |
p. 157-161 |
artikel |
14 |
Coflow Combustion in Granulated Ti + xC Mixtures: Boundary Conditions for Convection-Driven Wave Propagation
|
Seplyarskii, B. S. |
|
2019 |
|
3 |
p. 183-186 |
artikel |
15 |
Coflow combustion of bulk-density and granulated Ni–Al mixtures
|
Seplyarskii, B. S. |
|
2015 |
|
3 |
p. 174-175 |
artikel |
16 |
Coflow Combustion of Composite (Ni + Al)–(Ti + C) Granules
|
Seplyarskii, B. S. |
|
2019 |
|
3 |
p. 207-209 |
artikel |
17 |
Coflow filtration combustion in a slit-like reactor: Simultaneous manifestation of fluid-dynamic and thermal instability
|
Aldushin, A. P. |
|
2014 |
|
3 |
p. 125-132 |
artikel |
18 |
Combustion and materials synthesis
|
Manukyan, K. V. |
|
2017 |
|
3 |
p. 143-144 |
artikel |
19 |
Combustion and structure formation in the mechanoactivated Cr-B system
|
Kurbatkina, V. V. |
|
2008 |
|
3 |
p. 189-194 |
artikel |
20 |
Combustion Initiation in Gas-Free Mixture by Local Hot Spot
|
Aldushin, A. P. |
|
|
|
3 |
p. 188-191 |
artikel |
21 |
Combustion joining of refractory materials
|
Mukasyan, A. S. |
|
2007 |
|
3 |
p. 154-168 |
artikel |
22 |
Combustion of bulk density powder mixtures in a coflow of inert gas: 6*(Fe2O3 + 2Al) + 30% Al2O3 mixtures
|
Brauer, G. B. |
|
2009 |
|
3 |
p. 157-162 |
artikel |
23 |
Combustion of bulk density powder mixtures in a coflow of inert gas: 4. Ti-Si and Zi-Al systems
|
Seplyarskii, B. S. |
|
2008 |
|
3 |
p. 199-205 |
artikel |
24 |
Combustion of cylindrical Ti + 0.5C compacts: Influence of mechanical activation, thermovacuum degassing, and ambient pressure
|
Kochetov, N. A. |
|
2016 |
|
3 |
p. 177-180 |
artikel |
25 |
Combustion of Fe2O3/TiO2/Al thermit mixtures in steel tubes
|
Kobyakov, V. P. |
|
2011 |
|
3 |
p. 172-175 |
artikel |
26 |
Combustion of granulated Ti + 0.5C mixtures in nitrogen coflow: Influence of hydrogen impurity in titanium
|
Tarasov, A. G. |
|
2014 |
|
3 |
p. 169-170 |
artikel |
27 |
Combustion of Granulated Ti–C–Ni Mixtures: Influence of Granule Size
|
Seplyarskii, B. S. |
|
|
|
3 |
p. 185-187 |
artikel |
28 |
Combustion of layered SHS systems: Thermal conditions at the interface
|
Boyarchenko, O. D. |
|
2015 |
|
3 |
p. 115-118 |
artikel |
29 |
Combustion of metallothermic mixtures FeO-Cr2O3-Al-C: Influence of carbon granularity and localization
|
Silyakov, S. L. |
|
2011 |
|
3 |
p. 211-213 |
artikel |
30 |
Combustion of Ni-Al blends: Influence of Al granulometry
|
Kochetov, N. A. |
|
2013 |
|
3 |
p. 170-172 |
artikel |
31 |
Combustion of porous solid reagent in quasi-isobaric flow of three-component gaseous reagent
|
Kostin, S. V. |
|
2013 |
|
3 |
p. 129-134 |
artikel |
32 |
Combustion of Ti–B Mixtures in Argon Coflow: Impact of H2 + B Reaction
|
Tarasov, A. G. |
|
2018 |
|
3 |
p. 198-199 |
artikel |
33 |
Combustion of Ti + C4H6O4 Powder Mixture in Argon: Coflow Effect
|
Tarasov, A. G. |
|
|
|
3 |
p. 154-157 |
artikel |
34 |
Combustion of TiO2-Al thermit mixtures containing C and Cs in air: Phase composition of products
|
Kobyakov, V. P. |
|
2011 |
|
3 |
p. 161-165 |
artikel |
35 |
Combustion of Ti-TiC blends in a coflow of nitrogen gas
|
Seplyarskii, B. S. |
|
2013 |
|
3 |
p. 173-175 |
artikel |
36 |
Combustion synthesis and electromagnetic properties of nanocrystalline Pb(Zr0.52Ti0.48)O3
|
Patil, N. D. |
|
2013 |
|
3 |
p. 141-146 |
artikel |
37 |
Combustion synthesis and the electric field: A review
|
Morsi, K. |
|
2017 |
|
3 |
p. 199-209 |
artikel |
38 |
Combustion synthesis and tribological properties of SiALON-based ceramic composites
|
Zhao, Y. S. |
|
2010 |
|
3 |
p. 172-177 |
artikel |
39 |
Combustion synthesis of nanocrystalline cerium hexaboride using citric acid as a fuel
|
Amalajyothi, K. |
|
2009 |
|
3 |
p. 151-153 |
artikel |
40 |
Combustion Synthesis of YAG:Nd: Structural, Luminescent Characterization and Influence of Si Doping
|
Upasani, M. |
|
|
|
3 |
p. 145-152 |
artikel |
41 |
Combustion-Synthesized Ni–Cd Ferrites and their Structural, Magnetic, and Microwave Absorbing Properties
|
Shelar, M. B. |
|
2019 |
|
3 |
p. 173-178 |
artikel |
42 |
Compaction of green mixtures: Model experiments
|
Ponomarev, M. A. |
|
2010 |
|
3 |
p. 221-223 |
artikel |
43 |
Complex boride metal-matrix composites by SHS under high gravity
|
Sanin, V. N. |
|
2014 |
|
3 |
p. 151-160 |
artikel |
44 |
Composition and Structure of Ferrochromium SHS-Produced from (Mg,Fe)(Cr,Al)2O4 Ore Concentrate
|
Kachin, A. R. |
|
2018 |
|
3 |
p. 184-185 |
artikel |
45 |
Convection-Driven Combustion of Ti–C Granules in the Absence of External Gas Flow
|
Seplyarsii, B. S. |
|
|
|
3 |
p. 173-175 |
artikel |
46 |
Conversion degree in the head of spinning waves propagating in gas-solid SHS systems
|
Filimonov, I. A. |
|
2010 |
|
3 |
p. 169-171 |
artikel |
47 |
Corrosion Behavior of SHS-Produced Cu–Ti–B Composites
|
Mehrabani, S. A. N. |
|
|
|
3 |
p. 167-172 |
artikel |
48 |
Counterflow combustion in conditions of fluid-dynamic instability: Influence of reaction conditions on finger parameters
|
Aldushin, A. P. |
|
2015 |
|
3 |
p. 107-114 |
artikel |
49 |
Crystallization of Amorphous Antimony at Room Temperature: Non-Uniqueness of Patterning Route
|
Vadchenko, S. G. |
|
2018 |
|
3 |
p. 180-183 |
artikel |
50 |
Deep Oxidation/Hydrogenation Catalyst on a Boride–Oxide Support by SHS Method
|
Pugacheva, E. V. |
|
2019 |
|
3 |
p. 199-201 |
artikel |
51 |
Dehydrogenation of cyclohexane over SHS-produced Nickel-Zirconium alloy
|
Minasyan, V. T. |
|
2011 |
|
3 |
p. 150-152 |
artikel |
52 |
Dense AlON Ceramic by SHS under Nitrogen Gas Pressure
|
Akopdzhanyan, T. G. |
|
2019 |
|
3 |
p. 193-195 |
artikel |
53 |
Deposition of composite metallic coating onto Al through mechanical impregnation followed by thermal treatment
|
Vadchenko, S. G. |
|
2010 |
|
3 |
p. 178-185 |
artikel |
54 |
Discrete 2D Model of Combustion in a Binary Mixture Containing Mechanically Activated and Non-Activated Layers
|
Lapshin, O. V. |
|
|
|
3 |
p. 114-120 |
artikel |
55 |
Dynamic modes of infiltration-mediated combustion in a tubular reactor
|
Shkadinskaya, G. V. |
|
2008 |
|
3 |
p. 177-182 |
artikel |
56 |
Dynamic modes of Ti combustion in a coflow of N2-Ar mixture
|
Kochetov, N. A. |
|
2008 |
|
3 |
p. 206-209 |
artikel |
57 |
Effect of blend granulometry on calciothermic reduction of TiO2
|
Bayat, O. |
|
2012 |
|
3 |
p. 151-155 |
artikel |
58 |
Effect of mechanical activation on ignition and combustion of Ti-BN and Ti-SiC-C blends
|
Shkodich, N. F. |
|
2011 |
|
3 |
p. 191-199 |
artikel |
59 |
Effect of thermal treatment in vacuum on ignition of titanium compacts in hydrogen
|
Vadchenko, S. G. |
|
2010 |
|
3 |
p. 206-208 |
artikel |
60 |
Electrothermal explosion in cylindrical Ti-C charges covered with a TiC shell: A mathematical model
|
Bostandzhiyan, S. A. |
|
2012 |
|
3 |
p. 183-188 |
artikel |
61 |
Energetic Compositions by Mechanochemical Treatment of Metal Powders: 3. Influence of Activated and Modified Aluminum Particles on Combustion of Thermite SiO2–Al Mixtures
|
Bakkara, A. E. |
|
|
|
3 |
p. 165-169 |
artikel |
62 |
Extraction of ferrotungsten from ores with Low WO3 content
|
Golovchenko, N. |
|
2012 |
|
3 |
p. 156-161 |
artikel |
63 |
Fabrication and magnetic properties of submicro-textured magnetostrictive alloys
|
Martirosyan, K. S. |
|
2009 |
|
3 |
p. 207-212 |
artikel |
64 |
Features of Initiation and Combustion of Hf/PTFE Reactive Materials
|
Saikov, I. V. |
|
|
|
3 |
p. 200-207 |
artikel |
65 |
Field-activated pressure-assisted combustion synthesis of MoSi2
|
Gao, J. -Y. |
|
2008 |
|
3 |
p. 195-198 |
artikel |
66 |
Fluorophlogopite by metallothermic SHS from quartz sand and waste product
|
Loryan, V. E. |
|
2016 |
|
3 |
p. 155-158 |
artikel |
67 |
Forced SHS Compaction of TiB2–Ti: Structure and Properties
|
Bogatov, Yu. V. |
|
|
|
3 |
p. 239-241 |
artikel |
68 |
Forced SHS Compaction of TiC–NiTi Composites
|
Bogatov, Yu. V. |
|
|
|
3 |
p. 242-246 |
artikel |
69 |
Formation of porous structure in SHS products
|
Vadchenko, S. G. |
|
2010 |
|
3 |
p. 224-226 |
artikel |
70 |
Gasless Combustion in Combined Binary Mixtures Containing Low-Melting Reagent: Mathematical Model
|
Prokof’ev, V. G. |
|
|
|
3 |
p. 127-131 |
artikel |
71 |
Green Synthesis Approach for Nanosized Cobalt Doped Mg–Zn through Citrus Lemon Mediated Sol–Gel Auto Combustion Method
|
Kakati, S. S. |
|
|
|
3 |
p. 131-137 |
artikel |
72 |
Hard Facing of Exploclad Steel Bimetals by Metallothermic SHS
|
Yukhvid, V. I. |
|
2018 |
|
3 |
p. 186-188 |
artikel |
73 |
High-Entropy-Alloy Binder for TiC-Based Cemented Carbide by SHS Method
|
Rogachev, A. S. |
|
2019 |
|
3 |
p. 196-198 |
artikel |
74 |
High-gravity activated SHS of large bulk Al2O3/ZrO2 (Y2O3) nanocrystalline composites
|
Zhang, L. |
|
2009 |
|
3 |
p. 173-179 |
artikel |
75 |
High-porosity TiAl foam by volume combustion synthesis
|
Kamynina, O. K. |
|
2007 |
|
3 |
p. 137-140 |
artikel |
76 |
High-quality cemented carbides on the basis of near-nano and coarse-grain WC powders obtained by self-propagating high-temperature synthesis (SHS)
|
Zaitsev, A. A. |
|
2015 |
|
3 |
p. 152-160 |
artikel |
77 |
High-Temperature Synthesis of Nickel-Based Nanoparticles for Use as Materials in Sensors of Potentially Hazardous Gases
|
Tarttelin Hernández, P. |
|
2019 |
|
3 |
p. 159-172 |
artikel |
78 |
High-Temperature Synthesis of Ti–Si–B and Ti–Al–B Composites and Coatings
|
Lepakova, O. K. |
|
|
|
3 |
p. 150-156 |
artikel |
79 |
Hot forging of MAX compounds SHS-produced in the Ti-Al-C system
|
Stolin, A. M. |
|
2009 |
|
3 |
p. 194-199 |
artikel |
80 |
Icosahedral quasicrystalline Fe10Cu20Al70 by electrothermal explosion: Structural and magnetic properties
|
Bendjemil, B. |
|
2010 |
|
3 |
p. 209-213 |
artikel |
81 |
Influence of Ammonium Nitrate in the Synthesis of Alpha Tricalcium Phosphates (α-TCP) in One Step by Solution Combustion
|
Chavarriaga, E. A. |
|
|
|
3 |
p. 192-199 |
artikel |
82 |
Influence of CaO2 additives on the properties of Fe–WB-based composite lining deposited by centrifugal SHS on the inner surface of steel pipe
|
Singsarothai, S. |
|
2016 |
|
3 |
p. 181-185 |
artikel |
83 |
Inorganic Mn-Based Core–Shell Pigments by Solution-Combustion Synthesis with Citric Acid as a Fuel
|
Radishevskaya, N. I. |
|
|
|
3 |
p. 139-144 |
artikel |
84 |
In situ densification of SHS composites from nanoreactants
|
Dargar, S. R. |
|
2007 |
|
3 |
p. 125-132 |
artikel |
85 |
In situ monitoring of the kinetics of solid-gas SHS reactions: Application to the Zr-O2 system
|
Tingaud, D. |
|
2007 |
|
3 |
p. 110-118 |
artikel |
86 |
Interaction modes in Mo/Si diffusion couple at non-isothermal conditions
|
Kharatyan, S. L. |
|
2014 |
|
3 |
p. 138-140 |
artikel |
87 |
Kinetics of SHS reactions: A review
|
Mukasyan, A. S. |
|
2017 |
|
3 |
p. 145-165 |
artikel |
88 |
Long-lasting luminescence in garnet-based phosphors prepared by combustion synthesis
|
Yadav, P. J. |
|
2013 |
|
3 |
p. 157-162 |
artikel |
89 |
Magnesium Aluminate Spinel by SHS from the Elements
|
Grigoryan, R. A. |
|
2019 |
|
3 |
p. 202-203 |
artikel |
90 |
Magnetic properties and microstructure of SHS-Produced co-containing hexaferrites of the Me2W system
|
Naiden, E. P. |
|
2011 |
|
3 |
p. 200-207 |
artikel |
91 |
Magnetoelectric Composites yNi1−xCdxFe2O4 + (1 − y)Ba0.8Sr0.2TiO3 (x = 0.2, 0.4, 0.6; y = 0.15, 0.30, 0.45): Solution-Combustion Synthesis and Microwave Properties
|
Shelar, M. B. |
|
2018 |
|
3 |
p. 167-173 |
artikel |
92 |
Mechanically Activated SHS of Nb−Ti−Si Compounds
|
Trevino, R. |
|
|
|
3 |
p. 181-183 |
artikel |
93 |
Mechanoactivated SHS in the Ti–Ni System: Influence of Preheating Temperature
|
Kochetov, N. A. |
|
|
|
3 |
p. 162-166 |
artikel |
94 |
Mechanoactivation of Ni-Al blends in a ball mill: Influence of ball size
|
Kochetov, N. A. |
|
2014 |
|
3 |
p. 171-173 |
artikel |
95 |
Mechanochemical Synthesis of Ni–Cr3C2 Nanocomposite
|
Asgharzadeh, S. |
|
|
|
3 |
p. 144-153 |
artikel |
96 |
Melting Points of Refractory SHS Products: Evaluation by Molecular Dynamics Methods
|
Rogachev, S. A. |
|
|
|
3 |
p. 133-137 |
artikel |
97 |
Microstructure and properties of large bulk Al2O3/ZrO2 (Y2O3) composites prepared by SHS under high gravity
|
Liu, W. Y. |
|
2009 |
|
3 |
p. 180-185 |
artikel |
98 |
Microwave-assisted combustion synthesis and compaction of intermetallic-based functionally graded materials: Numerical simulation and experimental results
|
Rosa, R. |
|
2009 |
|
3 |
p. 163-172 |
artikel |
99 |
Models of SHS: An overview
|
Rogachev, A. S. |
|
2007 |
|
3 |
p. 141-153 |
artikel |
100 |
Mo5SiB2-Based Ceramics by Forced SHS Compaction and Hot Pressing of SHS-Produced Powders: Features of Phase-Formation Processes
|
Potanin, A. Yu. |
|
|
|
3 |
p. 143-149 |
artikel |
101 |
Nanocrystalline ZnO films deposited by spray pyrolysis: Effect of gas flow rate
|
Gaikwad, R. S. |
|
2012 |
|
3 |
p. 178-182 |
artikel |
102 |
Nanosized and large crystals of hexagonal boron nitride by SHS under high pressures of nitrogen gas
|
Loryan, V. E. |
|
2009 |
|
3 |
p. 154-156 |
artikel |
103 |
New MAX-Phased Cast Materials by Metallothermic SHS in the V–Nb–Al–C System
|
Gorshkov, V. A. |
|
|
|
3 |
p. 175-179 |
artikel |
104 |
NiAl-based electrodes by combined use of centrifugal SHS and induction remelting
|
Pogozhev, Yu. S. |
|
2016 |
|
3 |
p. 186-199 |
artikel |
105 |
NiMnxFe2 − xO4 ferrites: Combustion synthesis and characterization
|
Dmitriev, T. P. |
|
2014 |
|
3 |
p. 165-168 |
artikel |
106 |
Nitride-based materials SHS-produced from ferroalloys: I. potential application as catalysts, abrasives, and in film heaters
|
Chukhlomina, L. N. |
|
2015 |
|
3 |
p. 135-141 |
artikel |
107 |
Observation of Phase Transitions in the W–C System during Electrothermal Explosion under Pressure
|
Telepa, V. T. |
|
2019 |
|
3 |
p. 204-206 |
artikel |
108 |
Off-Stoichiometric NixCo3 –xO4 (x < 1) Spinels by Solution-Combustion Synthesis Using Citric Acid–Glycine Mixtures as a Dual Fuel
|
Zhuravlev, V. D. |
|
|
|
3 |
p. 170-174 |
artikel |
109 |
On combustion of boron in nitrogen gas
|
Loryan, V. E. |
|
2011 |
|
3 |
p. 153-155 |
artikel |
110 |
On possibility of formation of metastable compounds in a wave of gasless combustion
|
Lapshin, O. V. |
|
2014 |
|
3 |
p. 133-137 |
artikel |
111 |
On the 80th birthday of Alexander Grigor’evich Merzhanov
|
|
|
2011 |
|
3 |
p. 141-142 |
artikel |
112 |
Porous Ti–Co alloys and their joining with titanium by SHS cladding
|
Sytschev, A. E. |
|
2015 |
|
3 |
p. 171-173 |
artikel |
113 |
Preparation of Nanoparticles via Cellulose-Assisted Combustion Synthesis
|
Ashok, A. |
|
2018 |
|
3 |
p. 141-153 |
artikel |
114 |
Process stages during solution combustion synthesis of strontium aluminates
|
Tanaka, H. |
|
2013 |
|
3 |
p. 151-156 |
artikel |
115 |
Propagation Limits for Relay-Race Combustion in Case of Radiative Heat Transfer
|
Aldushin, A. P. |
|
2019 |
|
3 |
p. 191-192 |
artikel |
116 |
Protective Mo2NiB2–Ni coatings by centrifugal metallothermic SHS
|
Sanin, V. N. |
|
2015 |
|
3 |
p. 161-170 |
artikel |
117 |
Pure 2D-Nanopowders of Si2N2O by SHS under Nitrogen Pressure
|
Barinova, T. V. |
|
2019 |
|
3 |
p. 179-182 |
artikel |
118 |
Self-Propagating High-Temperature Synthesis and Consolidation of MoSi2–MoB Heterophase Ceramics Alloyed with ZrB2
|
Pogozhev, Yu. S. |
|
|
|
3 |
p. 221-232 |
artikel |
119 |
Self-propagating high temperature synthesis to produce CoCrMoC from elemental powders
|
Karsh, M. A. |
|
2011 |
|
3 |
p. 143-149 |
artikel |
120 |
Shock-assisted SHS in Ni-Al mixtures: Computer simulation
|
Leitsin, V. N. |
|
2009 |
|
3 |
p. 139-144 |
artikel |
121 |
SHS as a new approach to synthesizing hierarchical inorganic structures
|
Nersisyan, H. H. |
|
2017 |
|
3 |
p. 210-220 |
artikel |
122 |
SHS immobilization of cesium in mineral-like matrices
|
Barinova, T. V. |
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2007 |
|
3 |
p. 133-136 |
artikel |
123 |
SHS in mechanoactivated Ni-Al-W blends: Some structural aspects
|
Sytschev, A. E. |
|
2013 |
|
3 |
p. 166-169 |
artikel |
124 |
SHS in microgravity: Optimistic insight into the future
|
Sytschev, A. E. |
|
2009 |
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3 |
p. 200-206 |
artikel |
125 |
SHS in the Cu–Se System
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Nigmatullina, G. R. |
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p. 180-184 |
artikel |
126 |
SHS in the Nb–Si system: Separate mechanical alloying
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Shkoda, O. A. |
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2016 |
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3 |
p. 200-201 |
artikel |
127 |
SHS in the Ni–Al–Mn System: Influence of Mechanical Activation
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Kochetov, N. A. |
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p. 138-143 |
artikel |
128 |
SHS in the Ni–Al system: Influence of mechanical activation, vacuum heat treatment, and ambient pressure
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Kochetov, N. A. |
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2015 |
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3 |
p. 132-134 |
artikel |
129 |
SHS in the Si–CO2 System: Composition/Structure of Combustion Products
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Barinova, T. V. |
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p. 138-142 |
artikel |
130 |
SHS in the Zr–Al–C system: A time-resolved XRD study
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Kovalev, D. Yu. |
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2016 |
|
3 |
p. 149-154 |
artikel |
131 |
SHS joining of intermetallics with metallic substrates
|
Sytschev, A. E. |
|
2011 |
|
3 |
p. 185-190 |
artikel |
132 |
SHS Joining of Ti–C–Si Ceramics with Tantalum
|
Kamynina, O. K. |
|
2018 |
|
3 |
p. 192-194 |
artikel |
133 |
SHS of Al70Co15Ni15 and Al65Cu20Co15 Quasicrystals
|
Busurina, M. L. |
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|
3 |
p. 215-220 |
artikel |
134 |
SHS of a superoxide in the Na-Fe-Y-O system
|
Morozov, Yu. G. |
|
2011 |
|
3 |
p. 166-171 |
artikel |
135 |
SHS of MAX compounds in the Ti-Si-C system: Influence of mechanical activation
|
Vadchenko, S. G. |
|
2014 |
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3 |
p. 141-144 |
artikel |
136 |
SHS of α-Si3N4 from fine Si powders in the presence of blowing agents
|
Zakorzhevskii, V. V. |
|
2011 |
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3 |
p. 156-160 |
artikel |
137 |
SHS of single crystals in the B-C-Mg system: Crystal structure of new modification of B25C4Mg1.42 = [B12]2[CBC][C2]Mg1.42
|
Kovalev, I. D. |
|
2013 |
|
3 |
p. 163-165 |
artikel |
138 |
SHS of TiC–Ni Composites from Powdered and Granulated (Ti + C) + xNi Mixtures
|
Seplyarskii, B. S. |
|
2018 |
|
3 |
p. 189-191 |
artikel |
139 |
SHS production of heat-shield materials from minerals and residual products: Influence of preliminary mechanochemical treatment and modifying agents
|
Mansurov, Z. A. |
|
2016 |
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3 |
p. 166-172 |
artikel |
140 |
Silicon carbide ceramics SHS-produced from mechanoactivated Si–C–B mixtures
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Potanin, A. Yu. |
|
2015 |
|
3 |
p. 119-127 |
artikel |
141 |
Simultaneous synthesis and joining of a Ni-Al-Based layer to a Mo foil by SHS
|
Sytschev, A. E. |
|
2009 |
|
3 |
p. 213-216 |
artikel |
142 |
Simultaneous Thermal Analysis of Lithium Aluminate SCS-Precursors Produced with Different Fuels
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Zhuravlev, V. D. |
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3 |
p. 208-214 |
artikel |
143 |
Smart electroconductive textile by catalytic deposition of carbon nanotubes onto glass cloth
|
Smagulova, G. T. |
|
2016 |
|
3 |
p. 173-176 |
artikel |
144 |
Solid-state metathesis of KMgF3:Eu2+ phosphor
|
Ugemuge, N. S. |
|
2012 |
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3 |
p. 162-166 |
artikel |
145 |
Solution-Combustion Synthesis and Characterization of Fe3O4 Nanoparticles
|
Lesbayev, A. B. |
|
2018 |
|
3 |
p. 195-197 |
artikel |
146 |
Solution combustion synthesis for preparation of structured catalysts: A mini-review on process intensification for energy applications and pollution control
|
Specchia, S. |
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2017 |
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3 |
p. 166-186 |
artikel |
147 |
Solution Combustion Synthesis of Complex Oxide Semiconductors
|
Hossain, M. K. |
|
2018 |
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3 |
p. 129-140 |
artikel |
148 |
Solution-Combustion Synthesis of 4CuO/Al2O3 Composite from Starting Solutions Containing Copper Acetate as Ballast
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Zhuravlev, V. D. |
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3 |
p. 132-138 |
artikel |
149 |
Solution-Combustion Synthesis of LiNi1/3Co1/3Mn1/3O2 as a Cathode Material for Lithium-Ion Batteries
|
Zhuravlev, V. D. |
|
2018 |
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3 |
p. 154-161 |
artikel |
150 |
Solution-combustion synthesis of nanomaterials for lithium storage
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Wen, W. |
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2017 |
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3 |
p. 187-198 |
artikel |
151 |
Solution-combustion synthesis of oxide nanoparticles from nitrate solutions containing glycine and urea: Thermodynamic aspects
|
Khaliullin, Sh. M. |
|
2016 |
|
3 |
p. 139-148 |
artikel |
152 |
Some approaches to collecting electric voltage generated by SHS reactions
|
Morozov, Yu. G. |
|
2011 |
|
3 |
p. 208-210 |
artikel |
153 |
Spinning waves of infiltration-mediated combustion
|
Ivleva, T. P. |
|
2008 |
|
3 |
p. 157-167 |
artikel |
154 |
Strengthening Protective Boride Coatings with SHS-Produced Fe2Al5
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Aulov, V. F. |
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p. 184-186 |
artikel |
155 |
Structural and magnetic properties of SHS-produced multiphase W-Type hexaferrites: Influence of radiation-thermal treatment
|
Naiden, E. P. |
|
2015 |
|
3 |
p. 148-151 |
artikel |
156 |
Structural and mechanical properties of Sr-doped barium niobate thick films
|
Mathad, S. N. |
|
2014 |
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3 |
p. 145-150 |
artikel |
157 |
Structural, Electrical, and IR Properties of CuxCo1–xFe2O4 (x = 0, 0.4, 1.0) Prepared by Solid-State Method
|
Pujar, A. S. |
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2018 |
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3 |
p. 174-179 |
artikel |
158 |
Structural Macrokinetics of Combustion of Ti-Based Mixtures with Titanium Particles of Different Sizes
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Seplyarskii, B. S. |
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p. 233-238 |
artikel |
159 |
Superconducting Nb3Al by combustion synthesis: Structural characterization
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Hafs, A. |
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2016 |
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3 |
p. 159-165 |
artikel |
160 |
Surface and layer-by-layer modes of niobium combustion in nitrogen gas: Experiment and theory
|
Linde, A. V. |
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2009 |
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3 |
p. 145-150 |
artikel |
161 |
Surface Cladding by Combined Use of Metallothermy and Induction Heating
|
Silyakov, S. L. |
|
2019 |
|
3 |
p. 213-215 |
artikel |
162 |
Synthesis and structural characterization of nanosized nickel ferrite
|
Yattinahalli, S. S. |
|
2013 |
|
3 |
p. 147-150 |
artikel |
163 |
Synthesis of precursors in a high-energy mechanochemical reactor
|
Lapshin, O. V. |
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2013 |
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3 |
p. 135-140 |
artikel |
164 |
Synthesis of Ti3SiC2 by mechanically induced self-sustaining reaction: Some mechanistic aspects
|
Liang, B. Y. |
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2012 |
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3 |
p. 172-177 |
artikel |
165 |
The Influence of Ammonium Nitrate/Urea Ratio on the Reaction Process and Structure of Formed Alumina–Mullite Composite
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Feizabadi, E. |
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p. 121-130 |
artikel |
166 |
Thermal explosion in mechanically activated Ti–C system
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Lapshin, O. V. |
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2016 |
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3 |
p. 135-138 |
artikel |
167 |
Thermal explosion in Ti-Ni blends: Effect of interrupted mechanical activation
|
Kasatskii, N. G. |
|
2012 |
|
3 |
p. 167-171 |
artikel |
168 |
Thermal explosion in Ti–Ni blends: Influence of mechanocomposite size
|
Shkoda, O. A. |
|
2015 |
|
3 |
p. 128-131 |
artikel |
169 |
Thermally Coupled SHS Processes: Numerical Modeling
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Prokof’ev, V. G. |
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3 |
p. 109-113 |
artikel |
170 |
Thermal stability of FeAl intermetallics prepared by SHS sintering
|
Paris, S. |
|
2008 |
|
3 |
p. 183-188 |
artikel |
171 |
Thermit-type SiO2-Al reaction in arc discharge
|
Grishin, Yu. M. |
|
2011 |
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3 |
p. 181-184 |
artikel |
172 |
Ti–Al–C MAX Phases and Ti–C MXenes via SHS Route and Acid Leaching
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Shulpekov, A. M. |
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p. 159-164 |
artikel |
173 |
Titanium. Powder Metallurgy and SHS of Belarus. History and Prospect
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Savich, V. V. |
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p. 169-187 |
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174 |
Ti–Zr Alloy by Magnesiothermic Reduction and Acid Leaching: Influence of Process Conditions
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Ignat’eva, T. I. |
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2019 |
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p. 187-190 |
artikel |
175 |
To the theory of filtration combustion at high pressures of gas reagent
|
Grachev, V. V. |
|
2008 |
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3 |
p. 168-176 |
artikel |
176 |
Transformations of Iron (III) Precursors in a Wave of Flameless RDX Combustion
|
Mikhailov, Yu. M. |
|
2018 |
|
3 |
p. 162-166 |
artikel |
177 |
Two-dimensional model of infiltration-mediated combustion: Effect of heat losses
|
Grachev, V. V. |
|
2007 |
|
3 |
p. 105-109 |
artikel |
178 |
Unsteady Combustion Modes in Rectangular Rods
|
Prokof’ev, V. G. |
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2019 |
|
3 |
p. 155-158 |
artikel |