High strength weld metal design through nanoscale copper precipitation

Honghong Wang; Xinghua Yu; D. Isheim; D. Seidman; S. S. Babu

doi:10.1016/j.matdes.2013.03.093

High strength weld metal design through nanoscale copper precipitation

Honghong Wang^*, Xinghua Yu, D. Isheim, D. Seidman, S. S. Babu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

Deployment of advanced steels with superior yield and tensile strengths, as well as, toughness, ballistic and shock resistance is challenged by the lack of matching filler metals that can yield similar mechanical properties. In this research, strengthening of the weld metal through rapid formation of nanoscale copper precipitates, during reheating, within a ferrite matrix was proposed. A weld metal containing a nominal concentration of 2.49wt.% Cu, without any precipitation reaction, was soft 300HVN. On precipitation of nanoscale copper precipitates, with an average radius of 2.2±0.45nm and a high number density of 2.9×10²³m^-3, the hardness increased by 50-100HVN. The magnitude of this increase was inversely related to the peak temperature. The precipitation and extent of strengthening was rationalized based on thermodynamic calculations and Russell-Brown model, respectively.

Original language	English
Pages (from-to)	962-967
Number of pages	6
Journal	Materials and Design
Volume	50
DOIs	https://doi.org/10.1016/j.matdes.2013.03.093
Publication status	Published - Sept 2013
Externally published	Yes

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title = "High strength weld metal design through nanoscale copper precipitation",

abstract = "Deployment of advanced steels with superior yield and tensile strengths, as well as, toughness, ballistic and shock resistance is challenged by the lack of matching filler metals that can yield similar mechanical properties. In this research, strengthening of the weld metal through rapid formation of nanoscale copper precipitates, during reheating, within a ferrite matrix was proposed. A weld metal containing a nominal concentration of 2.49wt.\% Cu, without any precipitation reaction, was soft 300HVN. On precipitation of nanoscale copper precipitates, with an average radius of 2.2±0.45nm and a high number density of 2.9×1023m-3, the hardness increased by 50-100HVN. The magnitude of this increase was inversely related to the peak temperature. The precipitation and extent of strengthening was rationalized based on thermodynamic calculations and Russell-Brown model, respectively.",

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T1 - High strength weld metal design through nanoscale copper precipitation

AU - Wang, Honghong

AU - Yu, Xinghua

AU - Isheim, D.

AU - Seidman, D.

AU - Babu, S. S.

PY - 2013/9

Y1 - 2013/9

N2 - Deployment of advanced steels with superior yield and tensile strengths, as well as, toughness, ballistic and shock resistance is challenged by the lack of matching filler metals that can yield similar mechanical properties. In this research, strengthening of the weld metal through rapid formation of nanoscale copper precipitates, during reheating, within a ferrite matrix was proposed. A weld metal containing a nominal concentration of 2.49wt.% Cu, without any precipitation reaction, was soft 300HVN. On precipitation of nanoscale copper precipitates, with an average radius of 2.2±0.45nm and a high number density of 2.9×1023m-3, the hardness increased by 50-100HVN. The magnitude of this increase was inversely related to the peak temperature. The precipitation and extent of strengthening was rationalized based on thermodynamic calculations and Russell-Brown model, respectively.

AB - Deployment of advanced steels with superior yield and tensile strengths, as well as, toughness, ballistic and shock resistance is challenged by the lack of matching filler metals that can yield similar mechanical properties. In this research, strengthening of the weld metal through rapid formation of nanoscale copper precipitates, during reheating, within a ferrite matrix was proposed. A weld metal containing a nominal concentration of 2.49wt.% Cu, without any precipitation reaction, was soft 300HVN. On precipitation of nanoscale copper precipitates, with an average radius of 2.2±0.45nm and a high number density of 2.9×1023m-3, the hardness increased by 50-100HVN. The magnitude of this increase was inversely related to the peak temperature. The precipitation and extent of strengthening was rationalized based on thermodynamic calculations and Russell-Brown model, respectively.

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DO - 10.1016/j.matdes.2013.03.093

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SN - 0264-1275

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JO - Materials and Design

JF - Materials and Design

ER -

High strength weld metal design through nanoscale copper precipitation

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