Hydrogen-induced cracking by nanovoids in 310 stainless steel

Yizhong Huang; Qizhi Chen; Yanbin Wang; Wuyang Chu

doi:10.1007/bf02917009

Hydrogen-induced cracking by nanovoids in 310 stainless steel

Yizhong Huang^*, Qizhi Chen, Yanbin Wang, Wuyang Chu

^*Corresponding author for this work

University of Science and Technology Beijing

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

2 Citations (Scopus)

Abstract

Hydrogen-induced cracking was investigated by TEM in-situ tension in hydrogenated stainless steel of type 310. It was found experimentally that hydrogen-induced cracking happens via nanovoid nucleation followed by quasi-cleavage along {111} planes when C_H is higher. Otherwise, in the case of lower C_H, hydrogen enhances ductile fracture via hydrogen-enhanced microvoid nucleation, growth and connection. A new model was proposed based on the present experiments. Dislocations break away from defect atmospheres and move away from the DFZ, leaving vacancy and hydrogen clusters along : {111} planes. Hydrogen tends to combine with vacancy clusters and initiate nanovoids along {111} planes. Dense nanovoids connect each other, resulting in brittle cracking. Scattered nanovoids grow into microvoids or even macrovoids, leading to ductile fracture.

Original language	English
Pages (from-to)	372-382
Number of pages	11
Journal	Science in China, Series E: Technological Sciences
Volume	41
Issue number	4
DOIs	https://doi.org/10.1007/bf02917009
Publication status	Published - 1998
Externally published	Yes

ASJC Scopus Subject Areas

General Materials Science
General Engineering

Keywords

Dislocation
Hydrogen-induced cracking
Nanovoid
Stainless steel
TEM

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10.1007/bf02917009

Cite this

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title = "Hydrogen-induced cracking by nanovoids in 310 stainless steel",

abstract = "Hydrogen-induced cracking was investigated by TEM in-situ tension in hydrogenated stainless steel of type 310. It was found experimentally that hydrogen-induced cracking happens via nanovoid nucleation followed by quasi-cleavage along {111} planes when CH is higher. Otherwise, in the case of lower CH, hydrogen enhances ductile fracture via hydrogen-enhanced microvoid nucleation, growth and connection. A new model was proposed based on the present experiments. Dislocations break away from defect atmospheres and move away from the DFZ, leaving vacancy and hydrogen clusters along : {111} planes. Hydrogen tends to combine with vacancy clusters and initiate nanovoids along {111} planes. Dense nanovoids connect each other, resulting in brittle cracking. Scattered nanovoids grow into microvoids or even macrovoids, leading to ductile fracture.",

keywords = "Dislocation, Hydrogen-induced cracking, Nanovoid, Stainless steel, TEM",

author = "Yizhong Huang and Qizhi Chen and Yanbin Wang and Wuyang Chu",

year = "1998",

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language = "English",

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pages = "372--382",

journal = "Science in China, Series E: Technological Sciences",

issn = "1006-9321",

publisher = "Science in China Press",

number = "4",

}

TY - JOUR

T1 - Hydrogen-induced cracking by nanovoids in 310 stainless steel

AU - Huang, Yizhong

AU - Chen, Qizhi

AU - Wang, Yanbin

AU - Chu, Wuyang

PY - 1998

Y1 - 1998

N2 - Hydrogen-induced cracking was investigated by TEM in-situ tension in hydrogenated stainless steel of type 310. It was found experimentally that hydrogen-induced cracking happens via nanovoid nucleation followed by quasi-cleavage along {111} planes when CH is higher. Otherwise, in the case of lower CH, hydrogen enhances ductile fracture via hydrogen-enhanced microvoid nucleation, growth and connection. A new model was proposed based on the present experiments. Dislocations break away from defect atmospheres and move away from the DFZ, leaving vacancy and hydrogen clusters along : {111} planes. Hydrogen tends to combine with vacancy clusters and initiate nanovoids along {111} planes. Dense nanovoids connect each other, resulting in brittle cracking. Scattered nanovoids grow into microvoids or even macrovoids, leading to ductile fracture.

AB - Hydrogen-induced cracking was investigated by TEM in-situ tension in hydrogenated stainless steel of type 310. It was found experimentally that hydrogen-induced cracking happens via nanovoid nucleation followed by quasi-cleavage along {111} planes when CH is higher. Otherwise, in the case of lower CH, hydrogen enhances ductile fracture via hydrogen-enhanced microvoid nucleation, growth and connection. A new model was proposed based on the present experiments. Dislocations break away from defect atmospheres and move away from the DFZ, leaving vacancy and hydrogen clusters along : {111} planes. Hydrogen tends to combine with vacancy clusters and initiate nanovoids along {111} planes. Dense nanovoids connect each other, resulting in brittle cracking. Scattered nanovoids grow into microvoids or even macrovoids, leading to ductile fracture.

KW - Dislocation

KW - Hydrogen-induced cracking

KW - Nanovoid

KW - Stainless steel

KW - TEM

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JO - Science in China, Series E: Technological Sciences

JF - Science in China, Series E: Technological Sciences

IS - 4

ER -

Hydrogen-induced cracking by nanovoids in 310 stainless steel

Abstract

ASJC Scopus Subject Areas

Keywords

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