Abstrakt
This study investigates how the Cu concentration in Zr-Cu-N films affects the films' antibacterial capacity and mechanical properties. Zr-Cu-N films were prepared by reactive magnetron sputtering from composed Zr/Cu targets using a dual magnetron in an Ar + N-2 mixture.
The antibacterial capacity of Zr-Cu-N films was tested on Escherichia coli (E. coli) bacteria. The mechanical properties of Zr-Cu-N films were determined from the load vs. displacement curves measured using a Fisherscope H 100 microhardness tester.
The antibacterial capacity was modulated by the amount of Cu added to the Zr-Cu-N film. The mechanical properties were varied based on the energy E-i delivered to the growing film by bombarding ions.
It was found that it is possible to form Zr-Cu-N films with Cu concentrations >= 10 at. % that simultaneously exhibit (1) 100% killing efficiency E-k for E. coli bacteria on their surfaces, and (2) (1) high hardness H of about 25 GPa, (2) high ratio H/E* >= 0.1, (3) high elastic recovery W-c >= 60% and (4) compressive macrostress (sigma < 0). The Zr-Cu-N films with these parameters are flexible/antibacterial films that exhibit enhanced resistance to cracking.
This enhanced resistance was tested by (1) bending the Mo and Ti strip coated by sputtered Zr-Cu-N films (bending test) and (2) loading the surface of the Zr-Cu-N sputtered on a Si substrate by a diamond indenter at high loads up to 1 N (indentation test). Physical, mechanical, and antibacterial properties of Zr-Cu-N films are described in detail.
In summary, it can be concluded that Zr-Cu-N is a promising new material for creating flexible antibacterial coatings on contact surfaces. (C) 2015 American Vacuum Society.