Abstract
A combinatorial material adhesion study was used to optimize the composition of an adhesion promoting layer for a nanocrystalline diamond (NCD) coating on silicon. Three different adhesion promoting metals, namely W, Cr, and Ta, were selected to fabricate arrays of co-sputtered binary alloy films, with patches of seven different, distinct alloy compositions for each combination, and single element reference films on a single Si wafer (three wafers in total; W–Cr, Cr–Ta, Ta–W). Scratch testing was used to determine the critical failure load and practical work of adhesion for the NCD coatings as a function of adhesion layer chemistry. All tested samples eventually exhibit delamination of the NCD coating, with buckles radiating perpendicularly away from the scratch track. Application of any of the presented adhesion layers yields an increase of the critical failure load for delamination as compared to NCD on Si. While the influence of adhesion layers on the maximum buckle length is less pronounced, shorter buckles are obtained with pure W and Cr–Ta alloy layers. As a general rule, the addition of an adhesion layer showed a 75% improvement in the measured adhesion energies of the NCD films compared to the NCD coating without an adhesion layer, with specific alloys and compositions showing up to 125% increase in calculated practical work of adhesion.
Highlights
IntroductionThe method combines high-throughput synthesis and subsequent characterization of multinary material libraries on a single wafer, allowing for screening of unique properties or the optimization of specific properties for a desired application
We report the use of scratch testing to measure interfacial adhesion of nanocrystalline diamond coatings (NCD) as a function of combinatorially designed, adhesion promoting interlayers
Scratch testing is best used as a qualitative measure of adhesion, mainly for determining a comparative improvement in adhesion for a set system
Summary
The method combines high-throughput synthesis and subsequent characterization of multinary material libraries on a single wafer, allowing for screening of unique properties or the optimization of specific properties for a desired application. Regarding fabrication of such libraries, physical vapor deposition (PVD) such as magnetron sputtering with different targets is a common technique, using either co-deposition [5,7,8,9,10,11] or wedge-deposited multilayered thickness gradients of different elements combined with post-deposition annealing treatments for alloying [3,6,12]
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