Exceptional fatigue-resistant austenitic stainless steel for cryogenic applications

Chetan Singh; Taeho Lee; Keun Hyung Lee; You Sub Kim; E. Wen Huang; Jayant Jain; Peter K. Liaw; Soo Yeol Lee

doi:10.1016/j.apmt.2024.102195

Exceptional fatigue-resistant austenitic stainless steel for cryogenic applications

Chetan Singh, Taeho Lee, Keun Hyung Lee, You Sub Kim, E. Wen Huang, Jayant Jain, Peter K. Liaw, Soo Yeol Lee^*

^*此作品的通信作者

研究成果: Article › 同行評審

3 引文斯高帕斯（Scopus）

摘要

Most alloys change from ductile to brittle at cryogenic temperatures, whereas high-entropy alloys show better strength, ductility, and toughness. However, they suffer from cost and mass-production challenges. We discerned the fatigue behaviour of a cost-effective austenitic stainless steel, SS316L, at an ultra-low temperature (ULT) of 15 K. For the cryogenic applications, our work demonstrates that compared to room-temperature (RT), ULT exhibits eight times higher fatigue life, despite even higher applied stress [ σ_max=1.3×σ_{ys_RT/ULT} (280 MPa_RT; 517 MPa_{15 K})]. At 15 K, the fatigue mechanisms involve stacking faults, a two-step martensitic phase transformation (γ→ϵ→α^′) and α^′-martensite twinning, utilizing the applied fatigue strain efficiently. The remarkable improvement in the mechanical strength and fatigue life at ULT is the key to revolutionizing sustainable advancements in space exploration and energy storage.

原文	English
文章編號	102195
期刊	Applied Materials Today
卷	38
DOIs	https://doi.org/10.1016/j.apmt.2024.102195
出版狀態	Published - 6月 2024

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@article{fe0875d0833240538fab308ee8f58a75,

title = "Exceptional fatigue-resistant austenitic stainless steel for cryogenic applications",

abstract = "Most alloys change from ductile to brittle at cryogenic temperatures, whereas high-entropy alloys show better strength, ductility, and toughness. However, they suffer from cost and mass-production challenges. We discerned the fatigue behaviour of a cost-effective austenitic stainless steel, SS316L, at an ultra-low temperature (ULT) of 15 K. For the cryogenic applications, our work demonstrates that compared to room-temperature (RT), ULT exhibits eight times higher fatigue life, despite even higher applied stress [ σmax=1.3×σysRT/ULT (280 MPaRT; 517 MPa15 K)]. At 15 K, the fatigue mechanisms involve stacking faults, a two-step martensitic phase transformation (γ→ϵ→α′) and α′-martensite twinning, utilizing the applied fatigue strain efficiently. The remarkable improvement in the mechanical strength and fatigue life at ULT is the key to revolutionizing sustainable advancements in space exploration and energy storage.",

keywords = "Austenitic stainless steel, Cryogenic mechanical behavior, High cycle fatigue, Phase transformation, Ultra-low temperature",

author = "Chetan Singh and Taeho Lee and Lee, {Keun Hyung} and Kim, {You Sub} and Huang, {E. Wen} and Jayant Jain and Liaw, {Peter K.} and Lee, {Soo Yeol}",

note = "Publisher Copyright: {\textcopyright} 2024",

year = "2024",

month = jun,

doi = "10.1016/j.apmt.2024.102195",

language = "English",

volume = "38",

journal = "Applied Materials Today",

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T1 - Exceptional fatigue-resistant austenitic stainless steel for cryogenic applications

AU - Singh, Chetan

AU - Lee, Taeho

AU - Lee, Keun Hyung

AU - Kim, You Sub

AU - Huang, E. Wen

AU - Jain, Jayant

AU - Liaw, Peter K.

AU - Lee, Soo Yeol

PY - 2024/6

Y1 - 2024/6

N2 - Most alloys change from ductile to brittle at cryogenic temperatures, whereas high-entropy alloys show better strength, ductility, and toughness. However, they suffer from cost and mass-production challenges. We discerned the fatigue behaviour of a cost-effective austenitic stainless steel, SS316L, at an ultra-low temperature (ULT) of 15 K. For the cryogenic applications, our work demonstrates that compared to room-temperature (RT), ULT exhibits eight times higher fatigue life, despite even higher applied stress [ σmax=1.3×σysRT/ULT (280 MPaRT; 517 MPa15 K)]. At 15 K, the fatigue mechanisms involve stacking faults, a two-step martensitic phase transformation (γ→ϵ→α′) and α′-martensite twinning, utilizing the applied fatigue strain efficiently. The remarkable improvement in the mechanical strength and fatigue life at ULT is the key to revolutionizing sustainable advancements in space exploration and energy storage.

AB - Most alloys change from ductile to brittle at cryogenic temperatures, whereas high-entropy alloys show better strength, ductility, and toughness. However, they suffer from cost and mass-production challenges. We discerned the fatigue behaviour of a cost-effective austenitic stainless steel, SS316L, at an ultra-low temperature (ULT) of 15 K. For the cryogenic applications, our work demonstrates that compared to room-temperature (RT), ULT exhibits eight times higher fatigue life, despite even higher applied stress [ σmax=1.3×σysRT/ULT (280 MPaRT; 517 MPa15 K)]. At 15 K, the fatigue mechanisms involve stacking faults, a two-step martensitic phase transformation (γ→ϵ→α′) and α′-martensite twinning, utilizing the applied fatigue strain efficiently. The remarkable improvement in the mechanical strength and fatigue life at ULT is the key to revolutionizing sustainable advancements in space exploration and energy storage.

KW - Austenitic stainless steel

KW - Cryogenic mechanical behavior

KW - High cycle fatigue

KW - Phase transformation

KW - Ultra-low temperature

UR - http://www.scopus.com/inward/record.url?scp=85190789373&partnerID=8YFLogxK

U2 - 10.1016/j.apmt.2024.102195

DO - 10.1016/j.apmt.2024.102195

M3 - Article

AN - SCOPUS:85190789373

SN - 2352-9407

VL - 38

JO - Applied Materials Today

JF - Applied Materials Today

M1 - 102195

ER -

Exceptional fatigue-resistant austenitic stainless steel for cryogenic applications

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