Hydrogen embrittlement is a complex phenomenon, involving several length-and
timescales, that affects a large class of metals. It can significantly reduce the ductility and …

Hydrogen and fuels derived from it will serve as the energy carriers of the future. The
associated rapidly growing demand for hydrogen energy-related infrastructure materials has …

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 …

In Chap. 3, the relationships between microstructure and properties of dual-phase steels
were considered. These relationships serve as the foundation of “microstructure design” for …

The design of atomic-scale microstructural traps to limit the diffusion of hydrogen is one key
strategy in the development of hydrogen-embrittlement–resistant materials. In the case of …

We successfully achieved atomic scale visualization of hydrogen atoms at trap** sites
associated with the nano-sized precipitates of titanium carbide and vanadium carbide in …

The development of materials for automobile applications, especially for the body in white,
results from multiple and often contradictory constraints: a search for lightness, a high …

The broad compositional space of high entropy alloys (HEA) is conducive to the design of
HEAs with targeted performance. Herein, a data-driven and machine learning (ML) assisted …

Hydrogen will be a crucial pillar in the clean-energy foundation, and therefore, the
development of safe and cost-effective storage and transportation methods is essential to its …

In this work, the correlation between different microstructural components and hydrogen
trap** with high density in tempered niobium carbide (NbC)-precipitated martensitic steel …