What question did this study set out to answer?

This research aims to explore the phase transformation behavior and the mechanisms contributing to strengthening in Nb–Ti microalloyed steel.

April 22, 2026

Investigation of Phase Transformation Behavior and Strengthening Mechanisms in a Nb–Ti Microalloyed High‐Strength Steel

Key Points

This research aims to explore the phase transformation behavior and the mechanisms contributing to strengthening in Nb–Ti microalloyed steel.
Utilized a Gleeble‐3500 thermal‐mechanical simulation system for experiments.
Focused on cooling rates between 0.5–50°C/s to analyze phase evolution.
Examined mechanisms such as grain refinement and precipitation strengthening.
Ferrite was the primary phase at cooling rates of 0.5–5°C/s.
Bainite formed as the dominant phase at cooling rates of 10–50°C/s.
Higher cooling rates led to finer bainitic structures and increased hardness.

Abstract

The phase evolution behavior and the key mechanisms responsible for strengthening in a 750 MPa yield strength Nb–Ti microalloyed High‐strength steel were explored through the use of a Gleeble‐3500 thermal‐mechanical simulation system. The experimental data reveal that within the cooling rate interval of 0.5–5°C/s, ferrite constituted the primary phase. At cooling rates between 10 and 50°C/s, bainite was observed to form the prevailing phase in the microstructure. Furthermore, finer bainitic structures and higher hardness were obtained with increasing cooling rates. Under relatively low cooling rates ranging from 0.5 to 5°C/s, the principal strengthening mechanisms were identified as grain refinement and precipitation strengthening. The dominant precipitates responsible for this effect consisted of nanoscale (Ti, Nb)C particles.

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Investigation of Phase Transformation Behavior and Strengthening Mechanisms in a Nb–Ti Microalloyed High‐Strength Steel

Key Points

Abstract

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