Startseite Characterization of hydrogen assisted corrosion cracking of a high strength aluminum alloy
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Characterization of hydrogen assisted corrosion cracking of a high strength aluminum alloy

  • Xiao Yang

    Xiao Yang, born in 1985, graduated with Ph.D. in physical electronics. His fields of interest are micro-nano evaluation and failure analysis of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

     EMAIL logo     , Yan Liu

    Yan Liu, born in 1988, graduated with a master’s degree in materials science. Her fields of interest are the microstructure of metal materials. She works at the Luoyang Ship Material Research Institute, P. R. China.

         , Xian-feng Zhang

    Xian-Feng Zhang, born in 1988, graduated with a master’s degree in materials processing engineering. His fields of interest are the testing and evaluation of mechanical properties of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

         , Xue-feng Li

    Xue-Feng Li, born in 1972, graduated with a master’s degree in materials science. His fields of interest are the microstructure and failure analysis of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

         , Xin-yao Zhang

    Xin-Yao Zhang, born in 1980, graduated with a master’s degree in materials processing engineering. His fields of interest are micro-nano analysis and evaluation of metal materials. He works at the Luoyang Ship Material Research Institute and Henan Key Laboratory of Technology and Application Structural Materials for Ships and Marine Equipments, Luoyang 471,023 China.

         und Ling-qing Gao

    Ling-Qing Gao, born in 1964, graduated with a master’s degree in metal. His fields of interest are the testing and evaluation of metal materials and failure analysis. He works at the Luoyang Ship Material Research Institute and Henan Key Laboratory of Technology and Application Structural Materials for Ships and Marine Equipments, Luoyang 471023 China.
Veröffentlicht/Copyright: 7. Oktober 2022
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Abstract

Environmentally and hydrogen assisted cracking can occur during application of high-strength aluminum alloys. However, there are only few suitable laboratory procedures to characterize and evaluate the environmentally and hydrogen assisted cracking behavior of materials. By optimizing the hydrogen charging parameters and slow strain rate, a multidimensional test procedure was established, which could simulate the actual working environment and could realize the test and evaluation of hydrogen assisted cracking susceptibility in the laboratory. Moreover, it provides a new environmental adaptability evaluation method for the high-strength aluminum alloy materials.

Keywords: 7085 aluminum alloy; brittleness; hydrogen; hydrogen assisted cracking; testing and evaluation
Corresponding author: Xiao Yang, Luoyang Ship Material Research Institute, Luoyang, China, E-mail:

About the authors

Xiao Yang

Xiao Yang, born in 1985, graduated with Ph.D. in physical electronics. His fields of interest are micro-nano evaluation and failure analysis of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

Yan Liu

Yan Liu, born in 1988, graduated with a master’s degree in materials science. Her fields of interest are the microstructure of metal materials. She works at the Luoyang Ship Material Research Institute, P. R. China.

Xian-feng Zhang

Xian-Feng Zhang, born in 1988, graduated with a master’s degree in materials processing engineering. His fields of interest are the testing and evaluation of mechanical properties of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

Xue-feng Li

Xue-Feng Li, born in 1972, graduated with a master’s degree in materials science. His fields of interest are the microstructure and failure analysis of metal materials. He works at the Luoyang Ship Material Research Institute, P. R. China.

Xin-yao Zhang

Xin-Yao Zhang, born in 1980, graduated with a master’s degree in materials processing engineering. His fields of interest are micro-nano analysis and evaluation of metal materials. He works at the Luoyang Ship Material Research Institute and Henan Key Laboratory of Technology and Application Structural Materials for Ships and Marine Equipments, Luoyang 471,023 China.

Ling-qing Gao

Ling-Qing Gao, born in 1964, graduated with a master’s degree in metal. His fields of interest are the testing and evaluation of metal materials and failure analysis. He works at the Luoyang Ship Material Research Institute and Henan Key Laboratory of Technology and Application Structural Materials for Ships and Marine Equipments, Luoyang 471023 China.

  1. Author contributions: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.

  2. Research funding: None declared.

  3. Conflict of interest statement: The authors declare no conflicts of interest regarding this article.

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Published Online: 2022-10-07
Published in Print: 2022-10-26

© 2022 Walter de Gruyter GmbH, Berlin/Boston

Artikel in diesem Heft

  1. Frontmatter
  2. In situ corrosion fatigue life of 2198-T8 Al–Li alloy based on tests and DIC technique
  3. Characterisation of a wire arc additive manufactured 308L stainless steel cylindrical component
  4. Mechanical properties of a 7075-T6 aluminum alloy at elevated temperatures
  5. Low-velocity single and repeated impact behavior of 3D printed honeycomb cellular panels
  6. Fracture mechanical evaluation of the material HCT590X
  7. Effects of forging on the mechanical properties of B4Cp/Al composite with flaked Al and Al2O3 particles
  8. Homogenization effect on precipitation kinetics and mechanical properties of an extruded AA7050 alloy
  9. Low velocity impact response of sandwich composites with hybrid glass/natural fiber face-sheet and PET foam core
  10. Earing prediction of 2090-T3 aluminum-cups using a complete homogenous fourth-order polynomial yield function
  11. Imitation of human muscle by using an electromechanical system
  12. Reptile search algorithm and kriging surrogate model for structural design optimization with natural frequency constraints
  13. Online magnetic flux leakage detection of inclusions and inhomogeneities in cold rolled steel plate
  14. Characterization of hydrogen assisted corrosion cracking of a high strength aluminum alloy
  15. Influence of illuminance on indication detectability during visual testing
  16. Quality optimization of FDM-printed (fused deposition modeling) components based on differential scanning calorimetry
https://doi.org/10.1515/mt-2022-0079
Schlagwörter für diesen Artikel
7085 aluminum alloy; brittleness; hydrogen; hydrogen assisted cracking; testing and evaluation

Artikel in diesem Heft

  1. Frontmatter
  2. In situ corrosion fatigue life of 2198-T8 Al–Li alloy based on tests and DIC technique
  3. Characterisation of a wire arc additive manufactured 308L stainless steel cylindrical component
  4. Mechanical properties of a 7075-T6 aluminum alloy at elevated temperatures
  5. Low-velocity single and repeated impact behavior of 3D printed honeycomb cellular panels
  6. Fracture mechanical evaluation of the material HCT590X
  7. Effects of forging on the mechanical properties of B4Cp/Al composite with flaked Al and Al2O3 particles
  8. Homogenization effect on precipitation kinetics and mechanical properties of an extruded AA7050 alloy
  9. Low velocity impact response of sandwich composites with hybrid glass/natural fiber face-sheet and PET foam core
  10. Earing prediction of 2090-T3 aluminum-cups using a complete homogenous fourth-order polynomial yield function
  11. Imitation of human muscle by using an electromechanical system
  12. Reptile search algorithm and kriging surrogate model for structural design optimization with natural frequency constraints
  13. Online magnetic flux leakage detection of inclusions and inhomogeneities in cold rolled steel plate
  14. Characterization of hydrogen assisted corrosion cracking of a high strength aluminum alloy
  15. Influence of illuminance on indication detectability during visual testing
  16. Quality optimization of FDM-printed (fused deposition modeling) components based on differential scanning calorimetry
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