| Summary: | Nanofluids have emerged as a promising solution to the challenge of enhancing heat transfer in modern energy
applications. MXene-based nanofluids stand out due to their exceptional optical and thermophysical properties,
making them highly suitable for diverse industrial applications. However, challenges such as agglomeration and
stability have hindered their widespread commercial adoption despite their potential. This review provides a
comprehensive overview of MXene nanofluids, focusing on their synthesis, properties, and strategies to manage
accumulation and stability. The review highlights innovative approaches to mitigate agglomeration issues while
enhancing thermal properties and ensuring long-term stability in heating and cooling applications. The transformative
potential of MXene nanofluids extends to electronics, automotive cooling systems, renewable energy,
and biomedical applications. This review underscores the importance of future research efforts to examine the
stability and physical characteristics of MXene nanofluids thoroughly. By laying the groundwork for further
exploration, this review serves as a valuable resource for researchers seeking to optimize MXene nanofluids for
specific applications, promising improvements in heat transfer efficiency, economic feasibility, and environmental
sustainability compared to conventional heat transfer fluids.
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