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Effect of inert and reactive admixtures on the initiation and propagation of laminar spherical flames.
- Published in:
- Theoretical Foundations of Chemical Engineering, 2012, v. 46, n. 1, p. 80, doi. 10.1134/S004057951106011X
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- Article
Gas-phase nature of Si-N bond formation in the self-propagating high-temperature synthesis of silicon nitride by the azide method.
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- Theoretical Foundations of Chemical Engineering, 2010, v. 44, n. 4, p. 458, doi. 10.1134/S0040579510040159
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- Article
Numerical study of the effects of heterogeneous recombination and heterogeneous initiation on flame propagation in hydrogen-air mixtures at atmospheric pressure.
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- Theoretical Foundations of Chemical Engineering, 2010, v. 44, n. 3, p. 272, doi. 10.1134/S0040579510030061
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- Article
Phase formation in gas-phase combustion and pyrolysis reactions under spark and radio-frequency discharge conditions.
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- Theoretical Foundations of Chemical Engineering, 2009, v. 43, n. 4, p. 361, doi. 10.1134/S0040579509040022
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- Article
Effect of the vapors of organometallic compounds on the processes of ignition and combustion of hydrogen, propylene, and natural gas.
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- Theoretical Foundations of Chemical Engineering, 2009, v. 43, n. 2, p. 175, doi. 10.1134/S0040579509020079
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- Article
Effect of added reactive agents on the flame propagation velocity in rich hydrogen-air mixtures.
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- Theoretical Foundations of Chemical Engineering, 2008, v. 42, n. 6, p. 882, doi. 10.1134/S0040579508060109
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- Article
Ignition of coal powders in the presence of natural gas, oxygen, and reactive admixtures.
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- Kinetics & Catalysis, 2011, v. 52, n. 3, p. 348, doi. 10.1134/S0023158411030177
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- Article
High-speed color cinematography of chain self-ignition in the hydrogen, methane, and isobutylene oxidation reactions.
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- Kinetics & Catalysis, 2010, v. 51, n. 4, p. 475, doi. 10.1134/S0023158410040038
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- Article
Thermal Stability of Compact Pyrophoric Nickel Nanopowder Samples after Passivation.
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- Inorganic Materials, 2021, v. 57, n. 4, p. 351, doi. 10.1134/S0020168521040014
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- Article
Influence of Granulation and Ni-Containing Binder Composition on the Self-Propagating High-Temperature Synthesis of Carbides in the Ti–Cr–C System.
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- Inorganic Materials, 2020, v. 56, n. 9, p. 909, doi. 10.1134/S0020168520080142
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- Article
Phase Composition and Structure of Titanium Carbide/Nickel Binder Synthesis Products.
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- Inorganic Materials, 2019, v. 55, n. 11, p. 1104, doi. 10.1134/S0020168519110116
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- Article
The Chain Mechanism of the Effect of Dichlorodifluoromethane Additives on the Combustion of Hydrogen and Methane in Oxygen and Air.
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- Technical Physics, 2021, v. 66, n. 8, p. 929, doi. 10.1134/S1063784221060165
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- Article
Passivation of Compact Samples of Nickel Nanopowders and Modes of Their Interaction with Air.
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- Doklady Chemistry, 2020, v. 495, n. 1, p. 182, doi. 10.1134/S0012500820110014
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- Article
A New Approach to Performing Thermally Coupled Processes by the Example of a (Ni + Al)–(Ti + C) Granular Mixture.
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- Doklady Chemistry, 2019, v. 487, n. 1, p. 195, doi. 10.1134/S0012500819070024
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- Article
Synthesis of Nickel Nanoparticles with Controlled Pyrophoricity and Average Size.
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- Doklady Chemistry, 2019, v. 484, n. 1, p. 19, doi. 10.1134/S0012500819010014
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- Article
Effect of the Initial Temperature on the Modes of Passivation of Pyrophoric Powders: Macrokinetic Approach.
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- Doklady Chemistry, 2019, v. 484, n. 1, p. 24, doi. 10.1134/S001250081901004X
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- Article
Effect of Production Conditions on the Size of Copper Nanoparticles and the Modes of Ignition and Combustion of a Copper Nanopowder in Air.
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- Doklady Chemistry, 2018, v. 483, n. 2, p. 318, doi. 10.1134/S0012500818120054
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- Article
Passivation of iron nanopowders at temperatures below 0°C in a dry air atmosphere.
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- Doklady Chemistry, 2017, v. 477, n. 1, p. 261, doi. 10.1134/S0012500817110039
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- Article
Macrokinetic Analysis of Passivation of Pyrophoric Powders.
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- Doklady Physical Chemistry, 2018, v. 478, n. 1, p. 23, doi. 10.1134/S0012501618010062
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- Article
Modeling of producing chemically heterogeneous materials from a homogeneous mixture of reactants in thermal explosion mode.
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- Doklady Physical Chemistry, 2013, v. 451, n. 2, p. 192, doi. 10.1134/S0012501613080083
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- Article
Granulation in the powder technology of self-propagating high-temperature synthesis.
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- Russian Journal of NonFerrous Metals, 2013, v. 54, n. 3, p. 267, doi. 10.3103/S1067821213030024
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- Article
Role of Convective Heat Transfer in Gasless Combustion by the Example of Combustion of the Ti–C System.
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- Doklady Physical Chemistry, 2004, v. 398, n. 1-3, p. 203, doi. 10.1023/B:DOPC.0000041487.87644.26
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- Article
The Nature of the Anomalous Dependence of the Velocity of Combustion of “Gasless” Systems on the Sample Diameter.
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- Doklady Physical Chemistry, 2004, v. 396, n. 4-6, p. 130, doi. 10.1023/B:DOPC.0000033505.34075.0a
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- Article
Analytical Method of Calculation of the Temporal Characteristics of Ignition of Hybrid Gas–Solid Suspensions by a Heated Body.
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- Doklady Physical Chemistry, 2004, v. 394, n. 4-6, p. 50, doi. 10.1023/B:DOPC.0000018002.48306.02
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- Article
Reason for the Increasing Burning Rate of a Ti + C Powder Mixture Diluted with Copper.
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- Combustion, Explosion, & Shock Waves, 2023, v. 59, n. 3, p. 344, doi. 10.1134/S0010508223030097
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- Article
Macrokinetics of Combustion of Powder and Granular Titanium Mixtures with Different Allotropic Forms of Carbon.
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- Combustion, Explosion, & Shock Waves, 2022, v. 58, n. 3, p. 355, doi. 10.1134/S001050822203011X
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- Article
Combustion Macrokinetics of Granulated (Ti + C)–Ni Mixtures. Impact of Grain Size.
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- Combustion, Explosion, & Shock Waves, 2022, v. 58, n. 2, p. 178, doi. 10.1134/S001050822202006X
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- Article
Passivation of Compacted Samples Made of Pyrophoric Iron Nanopowders during Their Interaction with Air.
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- Combustion, Explosion, & Shock Waves, 2021, v. 57, n. 3, p. 326, doi. 10.1134/S0010508221030072
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- Article
Various Types of Combustion of a Ti + C Granular Mixture with a Different Content of the Gasifying Additive.
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- Combustion, Explosion, & Shock Waves, 2021, v. 57, n. 3, p. 334, doi. 10.1134/S0010508221030084
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- Article
Effect of a Ti + C Granule Size on Combustion in a Nitrogen Flow.
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- Combustion, Explosion, & Shock Waves, 2021, v. 57, n. 1, p. 60, doi. 10.1134/S001050822101007X
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- Article
Effect of Initial Temperature and Mechanical Activation on Synthesis in a Ti + Al System.
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- Combustion, Explosion, & Shock Waves, 2020, v. 56, n. 3, p. 308, doi. 10.1134/S0010508220030077
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Dependences of the Burning Rate and Phase Composition of Condensed Products of a Ti + Ni Mixture on the Mechanical Activation Time.
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- Combustion, Explosion, & Shock Waves, 2019, v. 55, n. 3, p. 300, doi. 10.1134/S0010508219030080
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- Article
Convective Combustion of a Ti + 0.5C Granulated Mixture. Domain of Existence and Fundamental Phenomena.
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- Combustion, Explosion, & Shock Waves, 2019, v. 55, n. 3, p. 295, doi. 10.1134/S0010508219030079
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Burning of the Ti + xC (1 > x > 0.5) powder and granulated mixtures.
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- Combustion, Explosion, & Shock Waves, 2016, v. 52, n. 6, p. 665, doi. 10.1134/S001050821606006X
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Impact of mechanical activation on the burning rate of pressed and bulk-density samples from a Ni + Al mixture.
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- Combustion, Explosion, & Shock Waves, 2016, v. 52, n. 3, p. 307, doi. 10.1134/S0010508216030084
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Dependence of burning rate on sample size in the Ni + Al system.
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- Combustion, Explosion, & Shock Waves, 2014, v. 50, n. 4, p. 393, doi. 10.1134/S0010508214040054
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- Article
Experimental investigation of combustion of a gasless pelletized mixture of Ti + 0.5C in argon and nitrogen coflows.
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- Combustion, Explosion, & Shock Waves, 2013, v. 49, n. 5, p. 555, doi. 10.1134/S0010508213050079
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Combustion of the gasless system Ti + 0.5C in a nitrogen coflow.
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- Combustion, Explosion, & Shock Waves, 2011, v. 47, n. 3, p. 294, doi. 10.1134/S0010508211030063
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- Article
Mechanism of reaction-front propagation in the Cr<sub>2</sub>O<sub>3</sub> + 2Al mixture.
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- Combustion, Explosion, & Shock Waves, 2010, v. 46, n. 3, p. 301, doi. 10.1007/s10573-010-0042-4
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- Article
Combustion of Ti+0.5C and Ti+C mixtures of bulk density in inert gas coflow.
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- Combustion, Explosion, & Shock Waves, 2009, v. 45, n. 1, p. 25, doi. 10.1007/s10573-009-0004-x
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- Article
Dynamic combustion regimes of the Ti-(Ti+0.5C) layered system in a concurrent nitrogen flow.
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- Combustion, Explosion, & Shock Waves, 2008, v. 44, n. 6, p. 655, doi. 10.1007/s10573-008-0099-5
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- Article
Mathematical Modeling of Chemical Conversion in Thin‐Layer Exothermic Mixtures under Periodic Electric‐Spark Discharges.
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- Combustion, Explosion, & Shock Waves, 2004, v. 40, n. 3, p. 302, doi. 10.1023/B:CESW.0000028943.14180.60
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- Article
Analysis of the Critical Conditions for Ignition of Gas–Particle Mixtures by a Heated Body with Pulsed Energy Supply.
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- Combustion, Explosion, & Shock Waves, 2004, v. 40, n. 2, p. 127, doi. 10.1023/B:CESW.0000020132.91058.63
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- Article
Approximate Analytical Method for Calculating the Time Characteristics of Ignition of a Gas Mixture by a Heated Body.
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- Combustion, Explosion, & Shock Waves, 2003, v. 39, n. 5, p. 496, doi. 10.1023/A:1026149415975
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- Article
Preparation and characterization of iron nanoparticles protected by an oxide film.
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- Inorganic Materials, 2017, v. 53, n. 9, p. 911, doi. 10.1134/S0020168517090011
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- Article
Experimental–Theoretical Determining of the Interphase Heat Transfer Coefficient in the Process of Combustion of a Granular SHS Mixture in a Gas Flow.
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- High Temperature, 2022, v. 60, n. 1, p. 73, doi. 10.1134/S0018151X22010163
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- Article