Residual stress within nanoscale metallic multilayer systems during thermal cycling

D. R. Economy, M. J. Cordill, E. A. Payzant, M. S. Kennedy

    Research output: Contribution to journalArticlepeer-review

    5 Scopus citations

    Abstract

    Projected applications for nanoscale metallic multilayers will include wide temperature ranges. Since film residual stress has been known to alter system reliability, stress development within new film structures with high interfacial densities should be characterized to identify potential long-term performance barriers. To understand factors contributing to thermal stress evolution within nanoscale metallic multilayers, stress in Cu/Nb systems adhered to Si substrates was calculated from curvature measurements collected during cycling between 25°C and 400°C. Additionally, stress within each type of component layers was calculated from shifts in the primary peak position from in-situ heated X-ray diffraction. The effects of both film architecture (layer thickness) and layer order in metallic multilayers were tracked and compared with monolithic Cu and Nb films (1μm total thickness). Analysis indicated that the thermoelastic slope of nanoscale metallic multilayer films (with 20nm and 100nm individual layer thicknesses) depends on thermal expansion mismatch, elastic modulus of the components, and also interfacial density. The layer thickness (i.e. interfacial density) affected thermoelastic slope magnitude (-1.23±0.09MPa/°C for 20nmCu/Nb vs. -0.89±0.03MPa/°C for 100nmCu/Nb) while layer order had minimal impact on stress responses after the initial thermal cycle (-0.82±0.07MPa/°C for 100nm Cu/Nb). When comparing stress responses of monolithic Cu and Nb films to those of the Cu/Nb systems, the nanoscale metallic multilayers show a similar increase in stress above 200°C to the Nb monolithic films, indicating that Nb components play a larger role in stress development than Cu. Phase specific stress calculations (Cu vs. Nb) from X-ray diffraction peak shifts in 20nm Cu/Nb collected during heating reveal that the component layers within a multilayer film respond similarly to their monolithic counterparts.

    Original languageEnglish
    Pages (from-to)289-298
    Number of pages10
    JournalMaterials Science and Engineering: A
    Volume648
    DOIs
    StatePublished - Nov 11 2015

    Funding

    In-situ heated XRD measurements were performed at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility. The authors wish to acknowledge the assistance of Dr. W. Heinz (K-AI GmbH), Dr. J. E. Harriss (Clemson University), Dr. L. V. Saraf (Clemson University), Mr. B. M. Schultz (Clemson University), Dipl.-Ing. S. P. Bigl (Montanuniversitaet Leoben), and Dr. T. Schöberl (Erich Schmid Institute) for their helpful discussions and guidance. This work was partially supported by funding from the Austrian Marshall Plan Foundation .

    FundersFunder number
    Marshallplan-Jubiläumsstiftung

      Keywords

      • Copper-Niobium
      • Nanoscale metallic multilayers
      • Residual stresses
      • Thermal expansion mismatch
      • Thermomechanical processing
      • Thin films

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