Mechanisms of oxide growth during the combustion of Al:Zr nanolaminate foils

Mechanisms of oxide growth during the combustion of Al:Zr nanolaminate foils

Reactive metal nanolaminates, most notably aluminum/zirconium composites, have been developed as fuels to aid combustion in explosive formulations. Thus far, however, their energy density is limited by incomplete oxidation. An in situ x-ray diffraction (XRD) study was performed on a 40 µm thick Al:Z...

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Bibliographic Details
Published in:Combustion and flame Vol. 191; no. C; pp. 442 - 452
Main Authors: Overdeep, Kyle R., Joress, Howie, Zhou, Lan, Livi, Ken J.T., Barron, Sara C., Grapes, Michael D., Shanks, Katherine S., Dale, Darren S., Tate, Mark W., Philipp, Hugh T., Gruner, Sol M., Hufnagel, Todd C., Weihs, Timothy P.
Format: Journal Article
Language:English
Published: New York Elsevier Inc 01-05-2018
Elsevier BV
Elsevier
Subjects:
Aluminum
Aluminum alloys
Aluminum oxide
Chemical reactions
Combustion
Cross-sections
Diffusion barriers
Diffusion layers
Diffusion rate
Electron probes
Energy & Fuels
Engineering
Explosive forming
Flux density
Foils
Formulations
Metal oxides
Multilayers
Nanocomposite
Nanoenergetic
Oxidation
Physical chemistry
Pyrometry
Reaction products
Switches
Synchrotron
Thermodynamics
Transmission electron microscopy
X-ray diffraction
Zirconium
Zirconium dioxide
Zirconium oxides
Zirconium
Nanocomposite
Oxidation
Nanoenergetic
Synchrotron
Aluminum
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Summary:Reactive metal nanolaminates, most notably aluminum/zirconium composites, have been developed as fuels to aid combustion in explosive formulations. Thus far, however, their energy density is limited by incomplete oxidation. An in situ x-ray diffraction (XRD) study was performed on a 40 µm thick Al:Zr (atomic ratio 1:1) multilayer foil to track the growth of reaction products during ignition, combustion, and cooling (over approximately 5 s) to determine the mechanisms that prevent complete combustion from occurring. Simultaneous pyrometry provides the ability to relate the observed phase progression to the foil temperature throughout the reaction, and post-reaction cross-sectional electron microprobe and transmission electron microscopy (TEM) of the combusted foils identify the location, composition, and microstructure of each product phase. We have used the combined results to develop an understanding of the growth mechanisms at play during the rapid reactions. The most significant finding is that the primary combustion product, orthorhombic ZrO2, grows linearly throughout the first 1.3 s of the reaction, indicating interface-limited growth, but then switches to slower diffusion-controlled growth. The transition in growth rate coincides with the abrupt end of a temperature plateau that is associated with self-sustained combustion. A thick (≈8 µm) Al2Zr layer is observed beneath the oxidized exterior in cross-sections of the reacted foil and is likely responsible for the reaction “turning off” before complete combustion is achieved. This underlying Al-rich intermetallic layer prevents the diffusion of aluminum away from the oxide interface, causing an increasing proportion of aluminum to oxidize. The resulting alumina creates a barrier to oxygen diffusion and is responsible for the incomplete combustion in air.
Bibliography:SC0004079; SC0016035
USDOE Office of Science (SC)
ISSN:0010-2180
1556-2921
DOI:10.1016/j.combustflame.2017.11.023