Effect of Oxide Shell Growth on nano-Aluminum Thermite Propagation Rates

Jeffrey Gesner; Michelle Pantoya; Valery Levitas

Effect of Oxide Shell Growth on nano-Aluminum Thermite Propagation Rates

Jeffrey Gesner, Michelle Pantoya, Valery Levitas

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Flame propagation rates for nanometric particle composites of aluminum (Al) and molybdenum trioxide (MoO ₃) were examined. The Al particles were prepared by thermally treating the particles at 480°C for time increments up to 180min in oxygen and 90min in argon. This treatment caused the aluminum passivation shell to grow and there is also evidence of shell damage due to treatment. Results reveal several interesting behaviors: flame speeds initially on the order of several hundred meters per second were reduced with damage to the oxide shell, and there is a weak dependence of the flame speed on the ratio of particle radius to shell thickness (M) in the range 6.1<M<13.4. The sharp drop in flame rate at further reduction in M down to 5.0 is consistent with a similar drop observed for adding alumina to the reactive mixture. All observations are consistent with the melt dispersion mechanism associated with Al nanoparticle oxidation.

Original language	English
Pages (from-to)	3448-3453
Journal	Combustion and Flame
State	Published - 2012

Cite this

@article{874541fa799c43b88373017d0a95696a,

title = "Effect of Oxide Shell Growth on nano-Aluminum Thermite Propagation Rates",

abstract = "Flame propagation rates for nanometric particle composites of aluminum (Al) and molybdenum trioxide (MoO 3) were examined. The Al particles were prepared by thermally treating the particles at 480°C for time increments up to 180min in oxygen and 90min in argon. This treatment caused the aluminum passivation shell to grow and there is also evidence of shell damage due to treatment. Results reveal several interesting behaviors: flame speeds initially on the order of several hundred meters per second were reduced with damage to the oxide shell, and there is a weak dependence of the flame speed on the ratio of particle radius to shell thickness (M) in the range 6.1<M<13.4. The sharp drop in flame rate at further reduction in M down to 5.0 is consistent with a similar drop observed for adding alumina to the reactive mixture. All observations are consistent with the melt dispersion mechanism associated with Al nanoparticle oxidation.",

author = "Jeffrey Gesner and Michelle Pantoya and Valery Levitas",

note = "Funding Information: The authors M. Pantoya and J. Gesner are grateful for support from the Army Research Office contract number W911NF-11-1-0439 and encouragement from our program manager, Dr. Ralph Anthenien. V. Levitas and M. Pantoya acknowledge support from NSF (CBET-0755236) Special thanks to Mr. Archis Marathe for TEM imaging and Mr. Corey Farley for TGA assistance.",

year = "2012",

language = "English",

pages = "3448--3453",

journal = "Combustion and Flame",

publisher = "Elsevier",

}

TY - JOUR

T1 - Effect of Oxide Shell Growth on nano-Aluminum Thermite Propagation Rates

AU - Gesner, Jeffrey

AU - Pantoya, Michelle

AU - Levitas, Valery

N1 - Funding Information: The authors M. Pantoya and J. Gesner are grateful for support from the Army Research Office contract number W911NF-11-1-0439 and encouragement from our program manager, Dr. Ralph Anthenien. V. Levitas and M. Pantoya acknowledge support from NSF (CBET-0755236) Special thanks to Mr. Archis Marathe for TEM imaging and Mr. Corey Farley for TGA assistance.

PY - 2012

Y1 - 2012

N2 - Flame propagation rates for nanometric particle composites of aluminum (Al) and molybdenum trioxide (MoO 3) were examined. The Al particles were prepared by thermally treating the particles at 480°C for time increments up to 180min in oxygen and 90min in argon. This treatment caused the aluminum passivation shell to grow and there is also evidence of shell damage due to treatment. Results reveal several interesting behaviors: flame speeds initially on the order of several hundred meters per second were reduced with damage to the oxide shell, and there is a weak dependence of the flame speed on the ratio of particle radius to shell thickness (M) in the range 6.1<M<13.4. The sharp drop in flame rate at further reduction in M down to 5.0 is consistent with a similar drop observed for adding alumina to the reactive mixture. All observations are consistent with the melt dispersion mechanism associated with Al nanoparticle oxidation.

AB - Flame propagation rates for nanometric particle composites of aluminum (Al) and molybdenum trioxide (MoO 3) were examined. The Al particles were prepared by thermally treating the particles at 480°C for time increments up to 180min in oxygen and 90min in argon. This treatment caused the aluminum passivation shell to grow and there is also evidence of shell damage due to treatment. Results reveal several interesting behaviors: flame speeds initially on the order of several hundred meters per second were reduced with damage to the oxide shell, and there is a weak dependence of the flame speed on the ratio of particle radius to shell thickness (M) in the range 6.1<M<13.4. The sharp drop in flame rate at further reduction in M down to 5.0 is consistent with a similar drop observed for adding alumina to the reactive mixture. All observations are consistent with the melt dispersion mechanism associated with Al nanoparticle oxidation.

M3 - Article

SP - 3448

EP - 3453

JO - Combustion and Flame

JF - Combustion and Flame

ER -

Effect of Oxide Shell Growth on nano-Aluminum Thermite Propagation Rates

Abstract

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