TITLE:
Nanoparticle-Enhanced Metal Alloys: Advances in Microstructural Control and Mechanical Performance, and Future Prospects
AUTHORS:
Olakunle Ibrahim Oresegun, Oyinlola Rukayat Obanla, Francis Mekunye, Tijesunimi Obed Akintunde, Oladipupo Praise Ogolo, Mariam Temitope Badmus, Reuben Zakari Kabantiyok, Ifeanyi Vincent Nwaneri, Joshua Oluwaseun Moore, Deborah Oluwadunsi Josiah, Maseala Camilla Sekete, Timothy Adewale Adeyi
KEYWORDS:
Metal Matrix Composite, Nanoparticle, Metal Alloys, Microstructural, Mechanical Performance
JOURNAL NAME:
World Journal of Nano Science and Engineering,
Vol.16 No.2,
June
30,
2026
ABSTRACT: Nanoparticle-enhanced metal alloys (NEMAs) represent a significant advancement in materials engineering, effectively overcoming the performance limitations of traditional alloys in extreme mechanical, thermal, and corrosive environments. This study aims to conduct a systematic review and synthesis of empirical research on NEMAs, focusing on trends in microstructural control, mechanical performance, and processing strategies, and identifying potential future research directions. A comprehensive content analysis was performed on peer-reviewed studies sourced from major databases, concentrating on various nanoparticle types, alloy systems, fabrication techniques, particle dispersion, and the resulting mechanical and microstructural outcomes. The analysis reveals that ceramic, metallic, carbon-based, and hybrid nanoparticles effectively refine grain structures, improve interfacial bonding, and activate strengthening mechanisms, including Hall-Petch and Orowan effects. The outcome results in improvements in hardness, tensile strength, wear resistance, and fatigue performance. Processing techniques such as stir casting, powder metallurgy, friction stir processing, and additive manufacturing significantly impact dispersion uniformity and mechanical reliability. Additionally, hybrid systems serve to alleviate strength-ductility trade-offs. Despite advancements, challenges remain in nanoparticle agglomeration, interfacial stability, long-term durability, and industrial scalability. The study concluded that selecting optimized nanoparticles, implementing hybrid reinforcement strategies, utilizing advanced processing techniques, and applying predictive modelling are essential for effectively translating laboratory achievements into high-performance industrial applications. Future research should focus on controlling dispersion, assessing durability, and developing scalable manufacturing techniques.