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2023 | Book

Fundamentals of Hydrogen Embrittlement

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About this book

This book is the second edition of the one originally published in 2016, as the first comprehensive treatment on the fundamentals of hydrogen embrittlement of metallic materials, mainly steel. The book provides students and researchers engaging in hydrogen problems with a unified view of the subject. Establishing reliable principles for materials design against hydrogen embrittlement and assessing their performance are recent urgent industrial needs in developing high-strength steel for hydrogen energy equipment and weight-reducing vehicles. The interdisciplinary nature of the subject, covering metal physics, materials science, and mechanics of fracture, has disturbed a profound understanding of the problem. In this book, previous studies are critically reviewed, and supplemental descriptions of fundamental ideas are presented when necessary. Emphasis is placed on experimental facts, with particular attention to their implication rather than phenomenological appearance. The adopted experimental conditions are also noted since the operating mechanism of hydrogen might differ by material and environment. For theories, employed assumptions and premises are noted to examine their versatility. Progress in the past decade in experimental and theoretical tools is remarkable and has nearly unveiled characteristic features of hydrogen embrittlement. Proposed models have almost covered feasible aspects of the function of hydrogen. This second edition has enriched the contents with recent crucial findings. Chapters on the manifestation of embrittlement in the deterioration of mechanical properties and microscopic features are reorganized, and the description is revised for the convenience of readers’ systematic understanding. A new chapter is created for delayed fracture in atmospheric environments as a conclusive subject of critical ideas presented in this book.

Table of Contents

Frontmatter
Chapter 1. Solid Solution
Abstract
Hydrogen equilibrium concentrations, locations, and energies in the regular lattice are presented mainly for iron and austenitic stainless steel. Atomistic calculations of electronic states and the heat of solution are included.
Michihiko Nagumo
Chapter 2. Hydrogen Trapping and Its Direct Detection
Abstract
The hydrogen concentration is crucial to the evolution of embrittlement, but most hydrogen atoms are trapped in various lattice defects, manifesting in the apparent hydrogen solubility and diffusivity.  The hydrogen thermal desorption analysis for detecting trapping is described with particular attention to its proper use, depending on the situation. Partitions of hydrogen among different traps are described for both equilibrium and transient states. Recent techniques to visualize hydrogen distributions in metals are also presented.
Michihiko Nagumo
Chapter 3. Interactions of Hydrogen with Lattice Defects
Abstract
Hydrogen interactions with various lattice defects are described, paying much attention to dislocations and strain-induced vacancies. Binding energies, hydrogen effects on defect densities, fractional hydrogen occupancies, and trapping configurations are presented with experimental methods to measure. Theoretical backgrounds and calculated results are also included.
Michihiko Nagumo
Chapter 4. Diffusion and Transport of Hydrogen
Abstract
Hydrogen diffusion coefficients in metals and their measuring methods, such as electrochemical permeation transients, are present. Effects of the diffusion process on diffusion coefficients are noticed, including stochastic treatments. Experimental bases for hydrogen transport by dislocations are described.
Michihiko Nagumo
Chapter 5. Deformation Behaviors
Abstract
Hydrogen effects on the elastic and plastic responses of iron and steel are reviewed for both macroscopic and microscopic behaviors. Effects of experimental conditions are noticed. Tentative explanations of the results and elastic/atomistic calculations of the dislocation mobility are described, and proposed basic ideas of hydrogen embrittlement mechanisms relating to dislocation dynamics are also presented.
Michihiko Nagumo
Chapter 6. Macroscopic Manifestations of Hydrogen Embrittlement
Abstract
 Deterioration of mechanical properties and premature fracture caused by hydrogen in various testing methods is described mostly for steel. Degradation manifests in diverse ways, and the effects of experimental conditions are noticed. Hydrogen effects in successive stages leading to fracture are paid attention to. Along with phenomenological behaviors, some model experiments devised to reveal the origin of degradation and the function of hydrogen are presented.
Michihiko Nagumo
Chapter 7. Microscopic Features Characterizing Hydrogen Embrittlement
Abstract
Hydrogen deterioration of mechanical properties manifests in diverse ways by testing methods, but some microscopic features are common associated with plasticity characterizing hydrogen effects. Fractographic features, strain localization, damage accumulation, and stress history effects are paid particular attention.
Michihiko Nagumo
Chapter 8. Microstructural Effects in Hydrogen Embrittlement of Steel
Abstract
As a help to steel design, microstructural and compositional effects on hydrogen embrittlement are reviewed for typical steel types. Control of a specific microstructural factor occasionally affects other factors, and deformation microstructures and cracking processes associated with observed degradation are remarked to characterize hydrogen effects.
Michihiko Nagumo
Chapter 9. Mechanistic Aspects of Fracture I—Brittle Fracture Models
Abstract
Brittle fracture models proposed as the mechanism of hydrogen embrittlement are presented. Notions based on the Griffith theory on crack instability and its criteria are explained. Hydrogen effects are included in the parameters used in the criteria. However, the involvement of plasticity is crucial even for brittle-like cases, and various expressions for the effects of plasticity in the crack instability criteria are described.
Michihiko Nagumo
Chapter 10. Mechanistic Aspects of Fracture II—Plasticity-Dominated Fracture Models
Abstract
Plasticity-dominated fracture models proposed as the mechanism of hydrogen embrittlement are reviewed together with a brief summary of basic notions on ductile fracture. Besides the origin of void nucleation and linking from microscopic aspects, constitutive relations are crucial for mechanistic aspects on plastic instability that leads to fracture. Hydrogen effects expressed as parameters in constitutive relations are noticed.
Michihiko Nagumo
Chapter 11. Delayed Fracture After Long Exposure in Atmospheric Environments
Abstract
The first exhibited details of the cracking process in delayed fracture of a high-strength steel bolt after long atmospheric exposure is presented as the conclusive chapter. The formation of frail zone beneath the thread root with multiple crack nucleation and the crack propagation associated with alterations of fractographic features from there are shown. Energetically peculiar situations as fracture event are noticed. The findings are in accord with the experimental and theoretical results of the hydrogen-enhanced strain-induced generation of vacancies. A method is proposed to assess the intrinsic susceptibility to delayed fracture of steel.
Michihiko Nagumo
Metadata
Title
Fundamentals of Hydrogen Embrittlement
Author
Michihiko Nagumo
Copyright Year
2023
Publisher
Springer Nature Singapore
Electronic ISBN
978-981-9909-92-6
Print ISBN
978-981-9909-91-9
DOI
https://doi.org/10.1007/978-981-99-0992-6

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