What question did this study set out to answer?

This research aims to develop a heat-resistant martensitic steel with improved creep resistance for use in power rotors.

February 13, 2026Open Access

Novel martensitic steel for ultra-supercritical power rotors: enhanced high-stress creep resistance via multi-element MC carbides

Key Points

This research aims to develop a heat-resistant martensitic steel with improved creep resistance for use in power rotors.
Designed a novel steel based on P91 with controlled compositions of C, Mo, V, and Cr, and added Ti and Ta.
Conducted creep testing at 650 °C to assess thermal stability and performance of the material.
Analyzed the orientation relationship between matrix and MC carbides.
Multi-component MC carbides showed exceptional thermal stability during testing.
Steel exhibited a significantly longer rupture time under high stress compared to conventional steels.
Observed improved dislocation pinning effects from nanoscale needle-like carbides.

Abstract

This study presents the design of a novel heat-resistant steel derived from the P91 steel, achieved through precise control of C, Mo, V, and Cr contents, along with the addition of Ti and Ta. We found that the multi-component MC carbides possess exceptional thermal stability, maintaining a stable orientation relationship with the matrix following 650 °C creep testing. Additionally, these nanoscale needle-like carbides exhibit a pronounced dislocation pinning effect. Consequently, this steel demonstrates an extended rupture time under high stress conditions compared to conventional steels, highlighting its considerable potential for applications in ultra-supercritical power rotors.

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Cite This Study

Jin et al. (Tue,) studied this question.

synapsesocial.com/papers/698ebf1d85a1ff6a930164d3 https://doi.org/https://doi.org/10.1080/21663831.2026.2624026

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