A focused review of the hydrogen storage tank embrittlement mechanism process

A focused review of the hydrogen storage tank embrittlement mechanism process

Hydrogen embrittlement is a widely known phenomenon in high-strength and storage materials. Hydrogen embrittlement is responsible for subcritical crack growth in material, fracture initiation, subsequent loss in mechanical properties, and catastrophic failure. Hydrogen is induced in the material dur...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 48; no. 35; pp. 12935 - 12948
Main Authors: Okonkwo, Paul C., Barhoumi, El Manaa, Ben Belgacem, Ikram, Mansir, Ibrahim B., Aliyu, Mansur, Emori, Wilfred, Uzoma, Paul C., Beitelmal, Wesam H., Akyüz, Ersin, Radwan, Ahmed Bahgat, Shakoor, R.A.
Format: Journal Article
Language:English
Published: Elsevier Ltd 26-04-2023
Subjects:
Degradation
Hydrogen diffusion
Hydrogen embrittlement
Materials
Storage tank
Degradation
Hydrogen diffusion
Hydrogen embrittlement
Storage tank
Materials
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Summary:Hydrogen embrittlement is a widely known phenomenon in high-strength and storage materials. Hydrogen embrittlement is responsible for subcritical crack growth in material, fracture initiation, subsequent loss in mechanical properties, and catastrophic failure. Hydrogen is induced in the material during an electrochemical reaction between the hydrogen, storage materials, and high-pressure gaseous hydrogen environment. Various mechanisms which are responsible for crack development, growth, and fracture have been deliberated and reported. However, the fundamental mechanism of hydrogen embrittlement remains unclear. Several techniques such as linearly increasing stress test techniques (LIST), constant extension rate test (CERT) and slow strain rate testing (SSRT), thermal desorption spectroscopy (TDS), permeation testing (PT), scanning electron microscopy (SEM), and transmission electron microscopy (TEM) have been utilized to determine the amount of hydrogen diffused and available in the hydrogen storage material. The review intends to categorize and provide a clear understanding of the degradation mechanism that occurs during hydrogen embrittlement. The improvement in mitigating the hydrogen embrittlement degradation as a function of modifying the structure and surfaces of the material is established. Prospects for addressing hydrogen embrittlement degradation through further experimental and numerical research are suggested. Lastly, this paper through recommendation endeavors to prevent hydrogen storage tank degradation and reduces high costs associated with the replacement of the component in renewable energy applications. •Hydrogen storage tank is critical in renewable energy.•Hydrogen tank performance can be enhanced by appropriate material selection.•Microstructural modification reduces the hydrogen embrittlement.•Embrittlement degradation mechanism affects hydrogen tank storage.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2022.12.252