An innovative radial gradient material design using hot isostatic pressing for applications in extreme environments

Daniel Yoon; Mohan Sai Kiran Kumar Yadav Nartu; Alex Michael Rogers; Isabella Johanna van Rooyen

doi:10.1016/j.jmapro.2025.07.059

An innovative radial gradient material design using hot isostatic pressing for applications in extreme environments

Daniel Yoon
, Mohan Sai Kiran Kumar Yadav Nartu
, Alex Michael Rogers
, Isabella Johanna van Rooyen

Fuel Cladding and Core Internals

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

1 Scopus citations

Abstract

Functionally graded materials (FGMs) are highly advanced continuous or discontinuous structures whose structural and material properties vary along a singular geometric dimension either in the axial or radial direction. The radial gradient FGM design makes for an optimal structural design to incorporate a bi-metallic structure with a copper-based high entropy alloy (Cu-HEA) with good mechanical properties and high irradiation resistance, and Chromium (Cr) with great corrosion resistance. This study focuses on the experimental design of a metal powder loading mechanism to fabricate a bi-metallic radial gradient structure using Cu-HEA and 99.9 % pure Cr metal powders. The powder loading strategy uses custom-designed concentric cylindrical dividers to separate the individual compositions. Two benchtop trial runs were performed for design optimization. The optimized design was then implemented to eventually load the HEA and Cr powders for consolidation via powder metallurgy hot isostatic pressing (PM-HIP). The electron microscopy analysis reveals the successful fabrication of the radial gradient structure with the chemical mapping analysis, demonstrating the gradual composition shift from the HEA at the center to the pure-Cr at the periphery via a three-step gradient.

Original language	English
Pages (from-to)	696-707
Number of pages	12
Journal	Journal of Manufacturing Processes
Volume	151
DOIs	https://doi.org/10.1016/j.jmapro.2025.07.059
State	Published - Oct 15 2025

Funding

We graciously thank the individuals from Oak Ridge National Laboratory's Nuclear Energy and Fuel Cycle Division and the Materials Science and Technology Division for their help in the powder consolidation process. From the Materials Science and Technology Division, Kevin Hanson, Caleb Eakens, Ryan Dalton performed powder loading experiments. From the ORNL's Nuclear Energy and Fuel Cycle Division, Alex Rogers performed HIP and processed HIP data and Caleb Massey oversaw logistics, coordination, and experiment planning. This work was supported by the Innovative Nuclear Materials (INM) program of the U.S. DOE Office of Nuclear Energy through the Battelle Memorial Institute [Contract No. DE-AC05-76RL01830]. This work was supported by the Innovative Nuclear Materials (INM) program of the U.S. DOE Office of Nuclear Energy through the Battelle Memorial Institute [Contract No. DE-AC05-76RL01830 ].

Keywords

High entropy alloys
Hot isostatic pressing (HIP)
Microstructural characterization
Powder loading mechanism
Radial gradient structures
Radiation and corrosion resistance

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10.1016/j.jmapro.2025.07.059

Cite this

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title = "An innovative radial gradient material design using hot isostatic pressing for applications in extreme environments",

abstract = "Functionally graded materials (FGMs) are highly advanced continuous or discontinuous structures whose structural and material properties vary along a singular geometric dimension either in the axial or radial direction. The radial gradient FGM design makes for an optimal structural design to incorporate a bi-metallic structure with a copper-based high entropy alloy (Cu-HEA) with good mechanical properties and high irradiation resistance, and Chromium (Cr) with great corrosion resistance. This study focuses on the experimental design of a metal powder loading mechanism to fabricate a bi-metallic radial gradient structure using Cu-HEA and 99.9 \% pure Cr metal powders. The powder loading strategy uses custom-designed concentric cylindrical dividers to separate the individual compositions. Two benchtop trial runs were performed for design optimization. The optimized design was then implemented to eventually load the HEA and Cr powders for consolidation via powder metallurgy hot isostatic pressing (PM-HIP). The electron microscopy analysis reveals the successful fabrication of the radial gradient structure with the chemical mapping analysis, demonstrating the gradual composition shift from the HEA at the center to the pure-Cr at the periphery via a three-step gradient.",

keywords = "High entropy alloys, Hot isostatic pressing (HIP), Microstructural characterization, Powder loading mechanism, Radial gradient structures, Radiation and corrosion resistance",

author = "Daniel Yoon and Nartu, \{Mohan Sai Kiran Kumar Yadav\} and Rogers, \{Alex Michael\} and \{van Rooyen\}, \{Isabella Johanna\}",

note = "Publisher Copyright: {\textcopyright} 2025",

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doi = "10.1016/j.jmapro.2025.07.059",

language = "English",

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AU - Yoon, Daniel

AU - Nartu, Mohan Sai Kiran Kumar Yadav

AU - Rogers, Alex Michael

AU - van Rooyen, Isabella Johanna

PY - 2025/10/15

Y1 - 2025/10/15

N2 - Functionally graded materials (FGMs) are highly advanced continuous or discontinuous structures whose structural and material properties vary along a singular geometric dimension either in the axial or radial direction. The radial gradient FGM design makes for an optimal structural design to incorporate a bi-metallic structure with a copper-based high entropy alloy (Cu-HEA) with good mechanical properties and high irradiation resistance, and Chromium (Cr) with great corrosion resistance. This study focuses on the experimental design of a metal powder loading mechanism to fabricate a bi-metallic radial gradient structure using Cu-HEA and 99.9 % pure Cr metal powders. The powder loading strategy uses custom-designed concentric cylindrical dividers to separate the individual compositions. Two benchtop trial runs were performed for design optimization. The optimized design was then implemented to eventually load the HEA and Cr powders for consolidation via powder metallurgy hot isostatic pressing (PM-HIP). The electron microscopy analysis reveals the successful fabrication of the radial gradient structure with the chemical mapping analysis, demonstrating the gradual composition shift from the HEA at the center to the pure-Cr at the periphery via a three-step gradient.

AB - Functionally graded materials (FGMs) are highly advanced continuous or discontinuous structures whose structural and material properties vary along a singular geometric dimension either in the axial or radial direction. The radial gradient FGM design makes for an optimal structural design to incorporate a bi-metallic structure with a copper-based high entropy alloy (Cu-HEA) with good mechanical properties and high irradiation resistance, and Chromium (Cr) with great corrosion resistance. This study focuses on the experimental design of a metal powder loading mechanism to fabricate a bi-metallic radial gradient structure using Cu-HEA and 99.9 % pure Cr metal powders. The powder loading strategy uses custom-designed concentric cylindrical dividers to separate the individual compositions. Two benchtop trial runs were performed for design optimization. The optimized design was then implemented to eventually load the HEA and Cr powders for consolidation via powder metallurgy hot isostatic pressing (PM-HIP). The electron microscopy analysis reveals the successful fabrication of the radial gradient structure with the chemical mapping analysis, demonstrating the gradual composition shift from the HEA at the center to the pure-Cr at the periphery via a three-step gradient.

KW - High entropy alloys

KW - Hot isostatic pressing (HIP)

KW - Microstructural characterization

KW - Powder loading mechanism

KW - Radial gradient structures

KW - Radiation and corrosion resistance

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DO - 10.1016/j.jmapro.2025.07.059

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SP - 696

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JO - Journal of Manufacturing Processes

JF - Journal of Manufacturing Processes

ER -

An innovative radial gradient material design using hot isostatic pressing for applications in extreme environments

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