Hydrogen embrittlement in metals (HE) is a serious challenge for the use of high strength
materials in engineering practice and a major barrier to the use of hydrogen for global …

Due to its characteristic of low stress brittle fracture, hydrogen embrittlement (HE) is a great
challenge for the alloys exposed to hydrogen-containing environments, threatening the …

Hydrogen embrittlement reduces the durability of the structural steels required for the
hydrogen economy. Understanding how hydrogen interacts with the materials plays a …

Hydrogen embrittlement is increasingly important in advanced high strength steels (AHHS)
as strength levels increase well above 1000 MPa. This work developed a detailed …

The precipitation of niobium carbide (NbC) is a superior approach to mitigating hydrogen
embrittlement (HE). The role of the semi-coherent interface between NbC and α-Fe on …

To couple strengthening with hydrogen-insensitive design in steels, many research employ
nanosized carbides to trap hydrogen atoms from diffusion. Herein, by using the pearlite steel …

Pt–Al compounds are promising high-temperature structural materials. However, the
hydrogenated behavior of Pt 3 Al is still unclear. To explore the hydrogenated mechanism …

Hydrogen drastically embrittles high-strength aluminum alloys, which impedes efforts to
develop ultrastrong components in the aerospace and transportation industries …

High-strength iron-based alloys serving in hydrogen-containing environments often faces a
critical problem of hydrogen embrittlement, which involves intricate mechanisms across …

Abstract Although Mo 3 Al 2 C MAX phase is a promising high temperature ceramics
because of the high temperature strength and excellent oxidation resistance, the structural …