Mg and its alloys evince strong candidature for biodegradable bone implants,
cardiovascular stents, and wound closing devices. However, their rapid degradation rate …

Magnesium (Mg) alloys are generally used in light-weight structural applications due to their
higher specific strength. However, the usage of these Mg alloys is limited due to their poor …

Magnesium alloys containing biocompatible components show tremendous promise for
applications as temporary biomedical devices. However, to ensure their safe use as …

Rising concerns about climate change drive the demand for lightweight components.
Magnesium (Mg) alloys are highly valued for their low weight, making them increasingly …

This paper deals with the development and present progress of biodegradable magnesium
alloys and emphasizes their transformative influence on the field of biomedical implants. In …

Magnesium alloys and their composites are fast replacing aluminum alloys and other
materials in the aerospace and automotive industries. Significant progress has been made …

The magnesium alloys are considered as biodegradable implant materials due to its
biocompatibility and mechanical properties. The light weight structure also made it more …

As the lightest structural metal material, magnesium alloy has the potential to replace
aluminum alloy and steel parts, but its development is limited by problems such as poor …

In the present work, fine grained AZ91 magnesium alloy–fly ash composite has been
successfully fabricated by friction stir processing. Microhardness measurements show …

Friction stir processing (FSP) is a promising technique to attain significant grain refinement
to improve the mechanical characteristics of magnesium (Mg) alloys. In the present study …