The continuous advancement of high-performance semiconductor chips has increased the demand for advanced packaging materials that can ensure stable performance and reliability. Among them, low-temperature solders with excellent thermal and mechanical properties are considered a key technology for next-generation electronic packaging. In this study, Pb-free Sn-58Bi solder reinforced with Ti3C2Tx MXene was developed using a solid-state ball milling process. The addition of Ti3C2Tx was found to refine the eutectic microstructure of the Sn-58Bi alloy and significantly improve its mechanical performance. The interfacial microstructure revealed that the thickness of intermetallic compound (IMC) formed between the solder bumps and ENIG substrates was effectively reduced by Ti3C2Tx incorporation. Mechanical evaluations were carried out through low- and high-speed shear tests. The low-speed shear test results showed a gradual increase in maximum shear load and toughness with increasing Ti3C2Tx content, achieving improvements of 76% and 72%, respectively, at 0.17 wt%. Fractographic analysis after high-speed shear testing indicated that Ti3C2Tx addition not only suppressed IMC growth but also promoted a fracture mode transition of solder bumps from brittle to ductile. These findings demonstrate that Ti3C2Tx/Sn-58Bi nanocomposite solder offers enhanced mechanical reliability and has strong potential as a low-temperature Pb-free solder for advanced electronic packaging applications.