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TiN-containing high-heat-input welding steels: Optimizing Ti/N ratio and precipitation temperature for enhanced low-temperature impact toughness in coarse-grained heat-affected zones

Junjie Hao, Chao Sheng Wang, Hua Duan, Yan Ping Zhu, Guo Yuan, Guodong Wang

2025Journal of Materials Research and Technology9 citationsDOIOpen Access PDF

Abstract

ABSTRACT To enhance the low-temperature impact toughness of the coarse-grained heat-affected zone (CGHAZ) in high-heat-input welding steels, TiN-containing steels with tailored Ti and N contents were designed. The effects of Ti/N ratio and TiN precipitation temperature on particle stability, austenite grain refinement, microstructural evolution, and low-temperature impact toughness were systematically investigated through in situ observations via high-temperature confocal laser scanning microscopy, thermodynamic modeling, and scanning electron microscopy. The results demonstrate that elevating the TiN precipitation temperature within austenite while reducing the Ti/N ratio enhances TiN thermal stability, thereby refining austenite grains (minimum size: 79.9 μm) and improving CGHAZ toughness (peak value: 227 ± 12 J at 400 kJ/cm heat input). However, excessive precipitation temperatures induce coarse TiN particles (2–4 μm) via liquid-phase precipitation, while excessively low Ti/N ratios elevate free nitrogen levels, both of which degrade toughness by promoting cleavage fracture initiation. A critical "ideal content region" was identified, balancing TiN stability (precipitation temperature: 10–20°C below solidus) and Ti/N ratio (2.0–2.5), which optimizes grain boundary pinning and minimizes embrittlement.

Topics & Concepts

Materials scienceTinToughnessMetallurgyPrecipitationWeldingComposite materialPhysicsMeteorologyMicrostructure and Mechanical Properties of SteelsMetal Alloys Wear and PropertiesMetal and Thin Film Mechanics
TiN-containing high-heat-input welding steels: Optimizing Ti/N ratio and precipitation temperature for enhanced low-temperature impact toughness in coarse-grained heat-affected zones | Litcius