Air and water oxidation of aluminum flake particles; Advanced Powder Technology; Vol. 307

Air and water oxidation of aluminum flake particles; Advanced Powder Technology; Vol. 307

Dettagli Bibliografici
Parent link:	Advanced Powder Technology: Scientific Journal Vol. 307.— 2017.— [P. 184–189]
Enti autori:	Национальный исследовательский Томский политехнический университет (ТПУ) Институт физики высоких технологий (ИФВТ) Кафедра технологии силикатов и наноматериалов (ТСН), Национальный исследовательский Томский политехнический университет (ТПУ) Энергетический институт (ЭНИН) Кафедра атомных и тепловых электростанций (АТЭС)
Altri autori:	Antipina S. A. Svetlana Anatolievna, Zmanovskii S. V. Sergey Vladislavovich, Gromov A. A. Aleksandr Aleksandrovich, Teipel U. Ulrich
Riassunto:	Title screen The article deals with the oxidation of aluminum flake particles with specific surface area ranged from 0.37 m2 /g to 0.73 m2 /g. The investigated powders which consisted of the above mentioned flake particles contained metal aluminum in high values (95-98 mass %). The powders possess a high hydrogen release rate (up to 27 cm3 /min) by the interaction with calcium hydroxide water solution. The powders under study revealed a high reactivity while oxidized in a non-isothermal mode in air. The reactivity parameter values for aluminum flake particles can be compared to those of aluminum spherical nanoparticles. The application of these aluminum flake particles were possible in two directions due to their high metal content in combination with low specific surface area and high reactivity: pyrotechnics and cellular concrete production. Режим доступа: по договору с организацией-держателем ресурса
Lingua:	inglese
Pubblicazione:	2017
Soggetti:	электронный ресурс труды учёных ТПУ aluminum oxidation алюминий наночастицы окисление реактивность
Accesso online:	http://dx.doi.org/10.1016/j.powtec.2016.12.009
Natura:	Elettronico Capitolo di libro
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=653215

Documenti analoghi

Heat release in chemical reaction between micron aluminum powders and water; International Journal of Hydrogen Energy; Vol. 44, iss. 52
Pubblicazione: (2019)

AC Electrochemical Copper and Aluminum Oxidation in Sodium Acetate Solutions; Procedia Chemistry; Vol. 10 : Chemistry and Chemical Engineering in XXI century
Pubblicazione: (2014)

Effect of the passivating coating type, particle size, and storage time on oxidation and nitridation of aluminum powders; Combustion, Explosion and Shock Waves; Vol. 42, № 2
Pubblicazione: (2006)

Characterization of Copper and Aluminum AC Electrochemical Oxidation Products; Procedia Chemistry; Vol. 10 : Chemistry and Chemical Engineering in XXI century
Pubblicazione: (2014)

Al–Cu Powder Oxidation Kinetics during Heating in Air; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 2
di: Korotkikh A. G. Aleksandr Gennadievich
Pubblicazione: (2022)

Laser Ignition of Aluminum and Boron Based Powder Systems; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 4
di: Korotkikh A. G. Aleksandr Gennadievich
Pubblicazione: (2022)

Numerical simulation of the high-temperature oxidation of a nanosize aluminum particle; Journal of Engineering Physics and Thermophysics; Vol. 94, iss. 1
Pubblicazione: (2021)

Oxidation of fine aluminum powders with water and air; Russian Journal of Physical Chemistry A; Vol. 91, iss. 1
Pubblicazione: (2017)

Oxidation of fine aluminum powders with water and air; Russian Journal of Physical Chemistry A; Vol. 91, iss. 1
Pubblicazione: (2017)

Нановолокнистые оксигидроксиды алюминия, модифицированные ионами марганца (II) - прекурсоры марганецсодержащих катализаторов глубокого окисления метана; Известия Томского политехнического университета [Известия ТПУ]; Т. 324, № 3 : Химия и химические технологии
Pubblicazione: (2014)

Intensification of bituminous coal and lignite oxidation by copper-based activating additives; International Journal of Coal Science and Technology; Vol. 8, iss. 1
Pubblicazione: (2021)

Production of nitride containing mixture in oxidation of aluminum powder in air; Glass and Ceramics; Vol. 55, iss. 3-4
Pubblicazione: (1998)

Кристаллические продукты сгорания в воздухе нанопорошка алюминия при действии магнитного поля; Известия Томского политехнического университета [Известия ТПУ]; Т. 323, № 2 : Математика и механика. Физика
di: Ильин А. П. Александр Петрович
Pubblicazione: (2013)

Combustion characteristics of high-energy material containing dispersed aluminum, boron, and aluminum borides; Combustion, Explosion and Shock Waves; Vol. 59, No. 4
Pubblicazione: (2023)

Non-isothermal oxidation of coal with Ce(NO3)3 and Cu(NO3)2 additives; International Journal of Coal Science and Technology; Vol. 6, iss. 1
di: Larionov K. B. Kirill Borisovich
Pubblicazione: (2019)

Thermal preparation and characterization of nanodispersed copper-containing powders produced by non-equilibrium electrochemical oxidation of metals; Solid State Sciences; Vol. 108
Pubblicazione: (2020)

Specific Features of Aluminum Nanoparticle Water and Wet Air Oxidation; AIP Conference Proceedings; Vol. 1683 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures
Pubblicazione: (2015)

Passivation of aluminum nanopowders for use in energetic materials; Combustion, Explosion, and Shock Waves; Vol. 9, iss. 1
Pubblicazione: (2015)

The influence of inorganic substances on oxidation characteristics of nanopowders: Electronic resources; The 9th Korea-Russia International Symposium on Science and Technology (KORUS 2005), June 26 - July 2, 2005, Novosibirsk State Technical University, Russia
Pubblicazione: (2005)

Combustion of agglomerated ultrafine aluminum powders in air; Combustion, Explosion, and Shock Waves; Vol. 38, № 6
Pubblicazione: (2002)

Silver catalysts for liquid-phase oxidation of alcohols in green chemistry: Challenges and outlook; Catalysis Today; Vol. 333
Pubblicazione: (2019)

Synthesis of titanium and zirconium nitrides by burning mixtures of their oxides with aluminum nanopowder in air; Refractories and Industrial Ceramics; Vol. 48, iss. 6
Pubblicazione: (2007)

Change in thermochemical properties of aluminum nanopowders upon irradiation with electron beam and microwave; Перспективы развития фундаментальных наук; Т. 2 : Химия
di: Badamasi N. M.
Pubblicazione: (2024)

Cytotoxicity of Oxidation Products of Al Nanoparticles to Neuro-2a and L929 Cells; AIP Conference Proceedings; Vol. 1683 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures
Pubblicazione: (2015)

More Insights into Support and Preparation Method Effects in Gold Catalyzed Glycerol Oxidation; Current Organic Synthesis; Vol. 14, iss. 3
Pubblicazione: (2017)

Experimental study of the processes of reducing the formation of sulfur oxides during the co-combustion of particles of metalignitous coal and wood processing waste; Fuel; Vol. 291
Pubblicazione: (2021)

Characterization of Aluminum powders I. Parameters of reactivityof Aluminum powders; Propellants, Explosives, Pyrotechnics; Vol. 27, № 6
Pubblicazione: (2002)

Mathematical Modeling of Combustion of a Mixture of Ultradisperse Aluminum Powder with Water; Journal of Engineering Physics and Thermophysics; Vol. 89, iss. 2
di: Krainov A. Yu.
Pubblicazione: (2016)

Characterization of Aluminum Powders: II. AluminumNanopowders Passivated by Non-Inert Coatings; Propellants, Explosives, Pyrotechnics; Vol. 31, iss. 5
di: Gromov A. A. Aleksandr Aleksandrovich
Pubblicazione: (2006)

Formation of a Surface Charged Microarc Coatings Modified by Boehmite Nanoparticles; Key Engineering Materials; Vol. 769 : High Technology: Research and Applications (HTRA 2017)
Pubblicazione: (2018)

Влияние добавки оксида магния на состав продуктов сгорания нанопорошка алюминия в воздухе; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 326, № 6
di: Ильин А. П. Александр Петрович
Pubblicazione: (2015)

Effect of redox treatments on activation and deactivation of gold nanospecies supported on mesoporous silica in CO oxidation; Fuel; Vol. 110 : IMCCRE 2012 “International-Mexican Congress on Chemical Reaction Engineering”
Pubblicazione: (2013)

Release and stability of aluminum metal nanoparticles in surface water: effects of particle loading; Перспективы развития фундаментальных наук
Pubblicazione: (2014)

Synthesis, luminescent and dosimetric properties of ultrafine oxide ceramics for high-dose dosimetry of ionizing radiation; Вестник Карагандинского университета. Физика; Bulletin of the Karaganda University. Physics; № 4 (116)
Pubblicazione: (2024)

The role of chemisorbed water in formation and stabilization of active sites on Pd/Alumina oxidation catalysts; Catalysis Today; Vol. 307
Pubblicazione: (2018)

Products of combustion of mixtures of aluminum and tungsten nanopowders in air; Combustion, Explosion, and Shock Waves; Vol. 43. № 4
di: Ilyin A. P. Aleksandr Petrovich
Pubblicazione: (2007)

Влияние добавки оксида кальция на состав продуктов сгорания нанопорошка алюминия в воздухе; Известия Томского политехнического университета [Известия ТПУ]; Т. 325, № 3 : Химия и химические технологии
di: Ильин А. П. Александр Петрович
Pubblicazione: (2014)

Влияние содержания марганца в оксогидрооксиде алюминия - прекурсоре MnOx-Al2O3 катализаторов - на каталитическую активность в реакции окисления С1-С3 углеводородов; Известия Томского политехнического университета [Известия ТПУ]; Т. 325, № 3 : Химия и химические технологии
Pubblicazione: (2014)

Влияние химических и фазовых превращений в оксидно-гидроксидной оболочке частиц алюминия различных размеров на закономерности их окисления при нагревании в воздухе; Известия Томского политехнического университета [Известия ТПУ]; Т. 325, № 3 : Химия и химические технологии
di: Коршунов А. В. Андрей Владимирович
Pubblicazione: (2014)

Formation Regularities of AlOOH Hollow Spheres during Aluminum Nanopowder Water Oxidation; AIP Conference Proceedings; Vol. 1683 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures
Pubblicazione: (2015)