Development of novel carbon-free cobalt-free iron-based hardfacing alloys with a hard π-ferrosilicide phase

Rahul Unnikrishnan; Alexander Carruthers; Sheng Cao; Samuel R. Rogers; Thomas W. J. Kwok; Rhys Thomas; David Dye; David Bowden; John A. Francis; Michael Preuss; Ed Pickering

doi:10.1016/j.mtla.2024.102107

Development of novel carbon-free cobalt-free iron-based hardfacing alloys with a hard π-ferrosilicide phase

Rahul Unnikrishnan, Alexander Carruthers, Sheng Cao, Samuel R. Rogers, Thomas W. J. Kwok, Rhys Thomas, David Dye, David Bowden, John A. Francis, Michael Preuss, Ed Pickering

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

Abstract

Recently, iron-based alloys with a π-ferrosilicide phase have emerged as potential
alternatives to cobalt-based hardfacing alloys. Here, we present the development of two π-ferrosilicide containing alloys: one with a ferritic matrix and the other with a ferriticaustenitic matrix. In the as-cast condition, both alloys revealed fine Ni- and Si-rich coherent cubic shaped D0₃ precipitates in the BCC matrix. The π-ferrosilicide phase was found to have an orientation relationship with the ferrite phase, nucleating within ferrite matrix and from ferrite grain boundaries. In contrast to carbide-strengthened hardfacing Fe-alloys, here the dissolution of the π-ferrosilicide phase at 1200^oC enables easy thermomechanical processing of these alloys, which results in refinement of the π-ferrosilicide and additional
formation of χ-phase precipitates in the ferrite. Nano-scratch tests provided evidence of a resilient silicide-ferrite interface, likely to due to it possessing some coherency. Both alloys also displayed compressive strengths approaching 2 GPa and ductility in compression of approximately 25%. The combination of processability and attractive mechanical properties suggests that these alloys have the potential to serve as alternatives to carbide-reinforced hardfacing Fe-alloys.

Original language	English
Article number	102107
Journal	Materialia
Volume	35
Early online date	2 May 2024
DOIs	https://doi.org/10.1016/j.mtla.2024.102107
Publication status	Published - 1 Jun 2024

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@article{0fbf9c033039453a966507efbb48465f,

title = "Development of novel carbon-free cobalt-free iron-based hardfacing alloys with a hard π-ferrosilicide phase",

abstract = "Recently, iron-based alloys with a π-ferrosilicide phase have emerged as potential alternatives to cobalt-based hardfacing alloys. Here, we present the development of two π-ferrosilicide containing alloys: one with a ferritic matrix and the other with a ferriticaustenitic matrix. In the as-cast condition, both alloys revealed fine Ni- and Si-rich coherent cubic shaped D03 precipitates in the BCC matrix. The π-ferrosilicide phase was found to have an orientation relationship with the ferrite phase, nucleating within ferrite matrix and from ferrite grain boundaries. In contrast to carbide-strengthened hardfacing Fe-alloys, here the dissolution of the π-ferrosilicide phase at 1200oC enables easy thermomechanical processing of these alloys, which results in refinement of the π-ferrosilicide and additional formation of χ-phase precipitates in the ferrite. Nano-scratch tests provided evidence of a resilient silicide-ferrite interface, likely to due to it possessing some coherency. Both alloys also displayed compressive strengths approaching 2 GPa and ductility in compression of approximately 25%. The combination of processability and attractive mechanical properties suggests that these alloys have the potential to serve as alternatives to carbide-reinforced hardfacing Fe-alloys. ",

author = "Rahul Unnikrishnan and Alexander Carruthers and Sheng Cao and Rogers, {Samuel R.} and Kwok, {Thomas W. J.} and Rhys Thomas and David Dye and David Bowden and Francis, {John A.} and Michael Preuss and Ed Pickering",

year = "2024",

month = jun,

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doi = "10.1016/j.mtla.2024.102107",

language = "English",

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TY - JOUR

T1 - Development of novel carbon-free cobalt-free iron-based hardfacing alloys with a hard π-ferrosilicide phase

AU - Unnikrishnan, Rahul

AU - Carruthers, Alexander

AU - Cao, Sheng

AU - Rogers, Samuel R.

AU - Kwok, Thomas W. J.

AU - Thomas, Rhys

AU - Dye, David

AU - Bowden, David

AU - Francis, John A.

AU - Preuss, Michael

AU - Pickering, Ed

PY - 2024/6/1

Y1 - 2024/6/1

N2 - Recently, iron-based alloys with a π-ferrosilicide phase have emerged as potential alternatives to cobalt-based hardfacing alloys. Here, we present the development of two π-ferrosilicide containing alloys: one with a ferritic matrix and the other with a ferriticaustenitic matrix. In the as-cast condition, both alloys revealed fine Ni- and Si-rich coherent cubic shaped D03 precipitates in the BCC matrix. The π-ferrosilicide phase was found to have an orientation relationship with the ferrite phase, nucleating within ferrite matrix and from ferrite grain boundaries. In contrast to carbide-strengthened hardfacing Fe-alloys, here the dissolution of the π-ferrosilicide phase at 1200oC enables easy thermomechanical processing of these alloys, which results in refinement of the π-ferrosilicide and additional formation of χ-phase precipitates in the ferrite. Nano-scratch tests provided evidence of a resilient silicide-ferrite interface, likely to due to it possessing some coherency. Both alloys also displayed compressive strengths approaching 2 GPa and ductility in compression of approximately 25%. The combination of processability and attractive mechanical properties suggests that these alloys have the potential to serve as alternatives to carbide-reinforced hardfacing Fe-alloys.

AB - Recently, iron-based alloys with a π-ferrosilicide phase have emerged as potential alternatives to cobalt-based hardfacing alloys. Here, we present the development of two π-ferrosilicide containing alloys: one with a ferritic matrix and the other with a ferriticaustenitic matrix. In the as-cast condition, both alloys revealed fine Ni- and Si-rich coherent cubic shaped D03 precipitates in the BCC matrix. The π-ferrosilicide phase was found to have an orientation relationship with the ferrite phase, nucleating within ferrite matrix and from ferrite grain boundaries. In contrast to carbide-strengthened hardfacing Fe-alloys, here the dissolution of the π-ferrosilicide phase at 1200oC enables easy thermomechanical processing of these alloys, which results in refinement of the π-ferrosilicide and additional formation of χ-phase precipitates in the ferrite. Nano-scratch tests provided evidence of a resilient silicide-ferrite interface, likely to due to it possessing some coherency. Both alloys also displayed compressive strengths approaching 2 GPa and ductility in compression of approximately 25%. The combination of processability and attractive mechanical properties suggests that these alloys have the potential to serve as alternatives to carbide-reinforced hardfacing Fe-alloys.

U2 - 10.1016/j.mtla.2024.102107

DO - 10.1016/j.mtla.2024.102107

M3 - Article

SN - 2589-1529

VL - 35

JO - Materialia

JF - Materialia

M1 - 102107

ER -

Development of novel carbon-free cobalt-free iron-based hardfacing alloys with a hard π-ferrosilicide phase

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