Effects of the Concentration of Inorganic Binders and Optical Absorbers on the Phase Formation and Microstructure of Flash‐Lamp‐Annealed Chemically Bonded Phosphate Ceramic Composites

Effects of the Concentration of Inorganic Binders and Optical Absorbers on the Phase Formation and Microstructure of Flash‐Lamp‐Annealed Chemically Bonded Phosphate Ceramic Composites

ABSTRACT A chemically bonded ceramic composite is synthesized using nanosized alumina powder and aluminum dihydrogen phosphate (Al(H2PO4)3, ADP) as a binder with varying solid volumetric ratios from 50% to 75%. Photonic curing of such composites by flash lamp annealing (FLA) is of interest as a new...

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Bibliographic Details
Main Authors: Eren Ozmen, Mark D. Losego
Format: Article
Language:English
Published: Wiley 2025-07-01
Series:International Journal of Ceramic Engineering & Science
Subjects:
manufacturing
layered ceramics
ultra–high temperature ceramics
Online Access:https://doi.org/10.1002/ces2.70019
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Summary:ABSTRACT A chemically bonded ceramic composite is synthesized using nanosized alumina powder and aluminum dihydrogen phosphate (Al(H2PO4)3, ADP) as a binder with varying solid volumetric ratios from 50% to 75%. Photonic curing of such composites by flash lamp annealing (FLA) is of interest as a new route to additive manufacturing of ceramics or rapidly producing ceramic coatings. ADP undergoes a condensation reaction with Al2O3 around 300°C–350°C and forms an AlPO4 compound that is thermally stable up to 1500°C due to strong P─O─Al bonds. Herein, an FLA system that can deliver tens of kilowatts per square centimeter of radiant energy is used to rapidly transform this ADP/Al2O3 mixture into this AlPO4 ceramic phase. An ADP fraction of about 55 vol% results in the lowest porosity layers having the best layer cohesion. Absorbance of the photonic energy emitted by the FLA's broadband xenon lamp (400–800 nm) is also critical to rapidly transforming these layers because optical absorbance is needed to convert the photonic energy to thermal energy. Three different optical absorbers—graphite, black iron oxide, and liquid black organic ink—are investigated as optical absorbers. Adding these absorbers is found to lower the required photonic input for ADP‐to‐AlPO4 conversion from ∼350 to ∼220 J/cm2, making the process even more energy efficient.
ISSN:2578-3270

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