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Fig. 1. Rocket nozzle via IR process (U.S. Patent No. 6,598,656, Sandhage, et al.)

Fig. 1. Rocket nozzle via IR process (U.S. Patent No. 6,598,656, Sandhage, et al.). Fig. 2. MgAl 2 O 4 particles on an Al 2 O 3 surface after immersion in Al-Mg(liq) for 0.5 h at 1100 o C. 12.0. 1100 o C. 10.0. 8.0. Cross-section of MgAl 2 O 4 layers.

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Fig. 1. Rocket nozzle via IR process (U.S. Patent No. 6,598,656, Sandhage, et al.)

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  1. Fig. 1. Rocket nozzle via IR process (U.S. Patent No. 6,598,656, Sandhage, et al.) Fig. 2. MgAl2O4 particles on an Al2O3 surface after immersion in Al-Mg(liq) for 0.5 h at 1100oC. 12.0 1100oC 10.0 8.0 Cross-section of MgAl2O4 layers (Layer Thickness)2 (X10-11 m2) 6.0 4.0 2.0 Al2O3 0.0 0 5 10 15 20 25 Time (104 sec) Fig. 3. MgAl2O4 layers on Al2O3 after immersion in Al-Mg(liq) for 168 h at 1000oC. Fig. 4. MgAl2O4 thickness vs. reaction time at 1100oC. Mechanisms of Incongruent Reduction (DMR-0341010)K. H. Sandhage, R. L. Snyder, Georgia Institute of Technology “Incongruent Reduction (IR)” refers to a fluid/ solid reaction that results in the reduction of a solid compound via the formation of an inter-mediate solid product. IR reactions have been used by the PI’s to produce very high-melting, erosion-resistant, lightweight rocket nozzles (Fig. 1). Such novel processing is an attractive and cost-effective means of manufacturing advanced ceramic composites with complex 3-D shapes for aerospace, automotive, energy production, and defense industries. This project is aimed at obtaining a basic understanding of the mechanism of IR in a model system: IR of Al2O3 by an Al-Mg melt, which occurs via formation of spinel, MgAl2O4. The spinel initially forms as oriented particles on an Al2O3 surface (Fig. 2). Further MgAl2O4 formation over time leads to a stack of continuous spinel layers on Al2O3 (Fig. 3). The rate of layer thickening obeys a parabolic law (Fig. 4), which is consistent with solid-state diffusion as the rate-limiting step.

  2. Mechanisms of Incongruent Reduction (DMR-0341010)K. H. Sandhage, R. L. Snyder, Georgia Institute of Technology • This research has been (Ohio State University, OSU) and is being (Georgia Institute of Technology, GIT) integrated with education via activities such as: • Integration into classroom lectures: l“Principles of Materials Science and Engineering” (MSE 605, Snyder/OSU) l“Materials Characterization” (MSE 715, Snyder/OSU) l”High-Temperature Corrosion” (MSE 736, Sandhage/OSU) • l“Introduction to Engineering” (MSE 1001, Sandhage/GIT) • l “Chemical and Environmental Properties of Materials” (MSE 8003J, Sandhage/GIT) • Integration into undergraduate research projects/senior theses on incongruent reduction-based processing (6 undergraduates have been involved to date): l“Ceramic body armor” (Mr. Jason Zielsdorf, supervised by Sandhage/OSU) l“Bulk metallic glass composites” (Mr. Geoff Lofstrom, Mr. Alex Tsai, supervised by Sandhage/OSU) l“Rocket nozzle composites” (Ms. Erin Beatty, Ms. Wendy Fu, Mr. James Sinclair, supervised by Sandhage/GIT)

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