Bulbul, FerhatKara, AdemBulbul, Leman ElifGunes, Kubra2026-02-282026-02-2820261047-48381543-1851https://doi.org/10.1007/s11837-025-07968-xhttps://hdl.handle.net/20.500.12403/5947This study explores the synergistic effects of graphite nanoparticles (0.1 wt.%) and thermal annealing (100-600 degrees C) on electroless Ni-B coatings for AISI 4140 steel. Graphite-enabled multifunctional performance-crystallization control, friction reduction, and antibacterial activity-are unlike conventional Ni-B systems. XRD showed amorphous-to-crystalline (Ni3B/Ni2B) transformation, with graphite acting as a nucleation agent below 300 degrees C before degrading at 600 degrees C. The 300 degrees C-annealed composite achieved optimal properties: 0.2 friction coefficient (75% lower than uncoated steel), 60% higher wear resistance, and hardness of 777 HV (+ 3.6% over as-deposited), attributed to graphite lubrication and nanocrystalline Ni3B formation. Antibacterial tests revealed a 3.4-mm inhibition zone against E. coli, though efficacy declined at higher temperatures due to graphite oxidation. All composites maintained superhydrophilicity (contact angle approximate to 0 degrees) without mechanical compromise. By correlating annealing temperature with microstructure, this work provides a design framework for Ni-B/graphite coatings combining low friction (mu = 0.2), high hardness (785 HV), and antibacterial functionality-addressing critical needs for wear-resistant, hygienic surfaces in biomedical and industrial applications.eninfo:eu-repo/semantics/closedAccessW COATINGSP/NI-BNICKELDEPOSITIONBEHAVIORWEARELECTRODEPOSITIONHARDNESSArticle7821421144610.1007/s11837-025-07968-x2-s2.0-105022624251Q2WOS:001616636100001Q2