The microstructure evolution and its influence on the mechanical properties are investigated in a hot-corrosion resistant Ni-based superalloy during long-term thermal exposure. It is found that the tertiary gamma' phase disappears and the secondary gamma' phase coarsens and coalesces gradually, which acts as the main reason for the decreasing of strength at both room temperature and 900 degrees C. During exposure, the grain boundary coarsens from discontinuous to half-continuous and finally to continuous structure. The optimum half-continuous grain boundary structure composed of discrete M23C6 and M3B2 wrapped by gamma' film leads to the elongation peak at room temperature in the thermally exposed specimens. At 900 degrees C, the increase in the elongation is attributed to the much softer matrix and the formation of microvoids. The behavior of primary MC decomposition is a diffusion-controlled process. During exposure, various derivative phases including M23C6, gamma', eta, M6C and sigma sequentially form in the decomposed region. Primary MC decomposition and the precipitation of sigma phase have little effect on the mechanical properties due to their low volume fractions. (C) 2012 Elsevier Ltd. All rights reserved.

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