Enhanced Multifaceted Properties of Nanoscale Metallic Multilayer Composites.
Mahmoud EbrahimiBangcai LuoQudong WangShokouh AttarilarPublished in: Materials (Basel, Switzerland) (2024)
This study explored the fascinating field of high-performance nanoscale metallic multilayer composites, focusing on their magnetic, optical, and radiation tolerance properties, as well as their thermal and electrical properties. In general, nanoscale metallic multilayer composites have a wide range of outstanding properties, which differ greatly from those observed in monolithic films. Their exceptional properties are primarily due to the large number of interfaces and nanoscale layer thicknesses. Through a comprehensive review of existing literature and experimental data, this paper highlights the remarkable performance enhancements achieved by the precise control of layer thicknesses and interfaces in these composites. Furthermore, it will discuss the underlying mechanisms responsible for their exceptional properties and provide insights into future research directions in this rapidly evolving field. Many studies have investigated these materials, focusing on their magnetic, mechanical, optical, or radiation-tolerance properties. This paper summarizes the findings in each area, including a description of the general attributes, the adopted synthesis methods, and the most common characterization techniques used. The paper also covers related experimental data, as well as existing and promising applications. The paper also covers other phenomena of interest, such as thermal stability studies, self-propagating reactions, and the progression from nanomultilayers to amorphous and/or crystalline alloys. Finally, the paper discusses challenges and future perspectives relating to nanomaterials. Overall, this paper is a valuable resource for researchers and engineers interested in harnessing the full potential of nanoscale metallic multilayer composites for advanced technological applications.
Keyphrases
- atomic force microscopy
- reduced graphene oxide
- high resolution
- high speed
- electronic health record
- molecularly imprinted
- room temperature
- radiation therapy
- mass spectrometry
- climate change
- artificial intelligence
- liquid chromatography
- radiation induced
- single molecule
- ionic liquid
- aqueous solution
- solid state
- simultaneous determination