The Effect of Second Tempering on Hydrogen Embrittlement of Ultra-High-Strength Steel

Wang, Zheng; Kan, Bo; Xu, Juanping; Li, Jinxu

doi:10.1007/s11661-020-05749-6

Cited by 11 publications

(1 citation statement)

References 34 publications

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“…Meanwhile, as the strength of a material increases, so does its vulnerability to HE (ultimately suggesting the avoidance of HSSs in any hydrogen storage applications even though it has various advantages as a storage material). Therefore, HE is a significant problem that limits the use of ultra-high-strength construction machinery martensitic steels for many purposes (16). HE has primarily been studied in stainless steel and high-strength low-alloy steel (HSLA).…”

Section: Material-based Storagementioning

confidence: 99%

Hydrogen Impermeable Materials for Efficient Hydrogen Storage

Meda¹,

Bhat²,

Agrawal

2022

ECS Trans.

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Hydrogen has the most potential as an energy resource alternative to fossil fuels, with numerous applications across sectors. It is clean and is present in a great amount in nature. However, due to the challenges in handling hydrogen and hydrogen embrittlement, its storage remains a concern, which is why high strength steels are rarely employed for such applications. To improve these hydrogen storage systems and address issues such as low energy efficiency, weight, long refueling periods, durability, hydrogen embrittlement, and costs, better hydrogen impermeable materials must be created. There are many material-based storage methods and coatings to reduce embrittlement and other problems faced by conventional storage methods like compression and liquefaction, but more investigation on high strength steels is necessary as they could be more efficient hydrogen storage materials.

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Section: Material-based Storagementioning

confidence: 99%