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An Insight Into Cyclic Oxidation behavior of ZrB2-20 Vol.% MoSi2 Based Ultrahigh Temperature Ceramic Matrix Composite
Abstract
In the context of hypersonic re-entry nosecones, subjected to repeated thermal shocks while descending through different layers of the atmosphere, with tremendously high velocities, it becomes extremely important to investigate the cyclic oxidation behavior of ultra-high temperature ceramics. The present study focuses on the cyclic oxidation law obeyed by ZrB2-20 vol.% MoSi2 composite during oxidation at temperatures ranging from 1100°C to 1300°C by carrying out six cycles for 6 h, at every individual temperature. The oxidation kinetic law has been estimated by measuring weight change at a different times for each temperature. The curves plotted between weight gain per unit area and exposure time (in second) having the R 2 (goodness of fit) values more than 0.9 are considered to be the accurate fit curves for defining correct oxidation law. Cyclic oxidation of ZrB2-MoSi2 composite follows linear rate law up to 1250°C, and for 1300°C, it follows parabolic rate law, which is diffusion-controlled process. Furthermore, XRD of the oxide layers has also been performed to analyze the scale formed, and scanning electron microscopy-energy dispersive spectroscopy of the oxide layer has also been performed to determine its thickness and its precise chemical composition in order to characterize the oxide layer.