High-temperature cyclic fatigue-crack growth behavior in an in situ toughened silicon carbide

Autor: X. F. Zhang, C. J. Gilbert, Robert O. Ritchie, Dongchang Chen
Rok vydání: 2000
Předmět:
Zdroj: Acta Materialia. 48:659-674
ISSN: 1359-6454
DOI: 10.1016/s1359-6454(99)00406-1
Popis: The growth of fatigue cracks at elevated temperatures (25-1300°C) is examined under cyclic loading in an in situ toughened, monolithic silicon carbide with Al-B-C additions (termed ABC-SiC), with specific emphasis on the roles of temperature, load ratio, cyclic frequency, and loading mode (static vs. cyc- lic). Extensive crack-growth data are presented, based on measurements from an electrical potential-drop crack-monitoring technique, adapted for use on ceramics at high temperatures. It was found that at equi- valent stress-intensity levels, crack velocities under cyclic loads were significantly faster than those under static loads. Fatigue thresholds were found to decrease with increasing temperature up to 1200°C; behavior at 1300°C, however, was similar to that at 1200°C. Moreover, no effect of frequency was detected (between 3 and 1000 Hz), nor evidence of creep cavitation or crack bridging by viscous ligaments or grain-boundary glassy phases in the crack wake. Indeed, fractography and crack-path sectioning revealed a fracture mode at 1200-1300°C that was essentially identical to that at room temperature, i.e. predominantly intergranular cracking with evidence of grain bridging in the crack wake. Such excellent crack-growth resistance is attrib- uted to a process of grain-boundary microstructural evolution at elevated temperatures, specifically invol- ving crystallization of the amorphous grain-boundary films/phases. © 2000 Acta Metallurgica Inc. Published by Elsevier Ltd. All rights reserved.
Databáze: OpenAIRE
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