http://imechanica.org/node/2712 Comments for "Elastic stress driven instabilities and break-up of multilayer thin films" en http://imechanica.org/node/2712 <p> Elastic stress driven morphological instabilities in thin films have been studied extensively: see Jesson et al, J. Elect. Mat., <strong>26</strong>, 9, pp., 1039-1047 (1997), for example, for a nice micrograph of rippling in Si-Ge system and a schematic of the explanation for the rippling. In the case of multilayer films, it is also well known that there could be&nbsp; post-growth morphological changes, and the layer geometry as well as the number of layers play a crucial role apart from the elastic constants in these changes; see the studies on a Gadolinia-Silica system by Sahoo et al for example -- Appl. Surf. Sci., <strong>252</strong>, pp. 1520-1537 (2005). In addition, there is also experimental evidence to show that in the case of multilayer films, there could be strong interactions between different layers of films:&nbsp; see the studies on Si/Ge multilayers by B Rahmati et al, Appl. Phys. A, <strong>62</strong>, pp. 575-579 (1996), for example.&nbsp; Finally, Sridhar et al (Acta Mater.,<strong> 45</strong>, 7, pp. 2715-2733 (1997)), using a linear stability analysis, showed that in embedded single and multilayer films, there could be two dominant modes of break-up, namely, symmetric and anti-symmetric. </p> <p> The linear stability analyses of the type used by Sridhar et al, however, are not ideal for a detailed quantitative study of the effect of elastic interactions and volume fraction; further, such analyses are also not meant for the study of long term evolution and final break-up of thin films. In a paper of ours (Chirranjeevi et al--submitted to Acta Materialia), we study elastic stress driven morphological instabilities and consequent break-up of thin film assemblies using a phase field model. </p> <p> Here are some of the salient conclusions from our study:&nbsp; </p> <ul> <li>Higher driving forces lead to an anti-symmetric onset of instability (and a lower value for the maximally growing wavelength;</li> <li>The driving force can be tuned through modulus mismatch, or elastic anisotropy, or film height;</li> <li>Volume fraction is an important independent parameter; increasing volume fraction increases interactions between layers (whose main effect is to reduce the driving force for destabilization) which result in increased inter-layer correlations, larger value for the maximally growing wavelength and a more symmetric onset; and,</li> <li>Inter-layer correlations, when they appear, appear from the very early stages -- even before the perturbations become discernible. </li> </ul> <p> For those of you interested in learning more about our studies, here is the preprint of our paper. </p> <br class="clear" /> http://imechanica.org/node/2712#comments research ATG elastic stress driven microstructural evolution multilayer thin film thin film Mon, 18 Feb 2008 23:16:24 -0500 Mogadalai Gururajan 2712 at http://imechanica.org