Tensile mechanical properties, constitutive equations, and fracture mechanisms of a novel 9% chromium tempered martensitic steel at elevated temperatures

To explore the high-temperature tensile behavior and fracture mechanism of a novel 9% chromium tempered martensitic steel, G115, a series of tensile tests were conducted at 625, 650, and 675 degrees C within the strain rate range of 5.2x10(-5)-5.2x10(-3) s(-1). The results demonstrated that the tensile strength decreased with increasing temperature and decreasing strain rate. However, the elongation to failure increased with increasing temperature. The ductility at 675 degrees C exhibited significant improvement. Furthermore, three typical constitutive equations were comparatively analyzed to accurately describe the tensile deformation behavior of G115 steel. A stress exponent of approximately 11.1 and an activation energy of approximately 639.865 kJ/mol were obtained via the hyperbolic sine law. To explain the actual deformation mechanism, the threshold stress concept was introduced. The modified hyperbolic sine constitutive equation was proposed to determine the threshold stress sigma(th), the true stress exponent n(1), and the true activation energy Q(1) of G115 steel. The Q(1) value increased with increasing temperature and strain rate. Dislocation climb was the dominant deformation mechanism under the tested conditions. In addition, fracture surface investigations revealed a typical ductile fracture mode with a dense array of dimples at 625 and 650 degrees C. However, transgranular facets with tear ridges were observed in the central region at 675 degrees C. In addition, the microstructures of the fracture frontier and longitudinal section away from the fracture surface were studied to further understand the fracture mechanism.