MZ helped to prepare samples WS measured the reflectance data M

MZ helped to prepare samples. WS measured the reflectance data. ML designed the experiments and wrote the manuscript. All authors read and approved the final manuscript.”
“Background Low-energy ion

beam sputtering (IBS) is considered to be a very promising and cost-effective technique to fabricate self-organized nanoscale periodic patterns on a large-area (up to 2- to 3-in. diameter) www.selleckchem.com/products/oligomycin-a.html solid surface in a single step [1]. Such nanoscale periodic structures (mostly ripples) are considered to be useful as templates for growth of nanofunctional thin films having potential applications in plasmonics, nanoscale magnetism, and other technological applications. For instance, Ag films deposited on rippled silicon substrate show strong optical

anisotropy [2, 3] and Fe films on rippled substrates ABT-263 ic50 demonstrate magnetic anisotropy which are driven by morphological anisotropy [4, 5]. Direct nanoscale ripple patterning can also induce in-plane uniaxial magnetic anisotropy in epitaxial [6] and polycrystalline ferromagnetic Fe or Ni films [7]. In another study, it has been shown that rippled Au films show anisotropy in electrical transport property [8]. It is well established that ripple characteristics depend on beam and target parameters, namely ion species, ion energy, ion flux, ion fluence, ion incident angle, composition, and sample temperature [9–17]. In addition, experimental studies have shown that evolution of ion beam-induced ripple morphology is related to continuous change in sputtering yield even at any given angle [18–20]. For instance, Stevie Idelalisib et al. reported that in the case of ripple formation at 52° (for 6 keV O2+ ions), the sputtering yield got enhanced by nearly

70% as compared to the initial value [21]. However, an accurate prediction of change in sputtering yield is still not well developed due to a complex nature of the problem (i.e. complex mechanisms leading to a surface morphology and the existing interplay between these mechanisms and change in sputtering yield). In addition to the experimental studies, there exist substantial amount of theoretical studies to explain IBS-induced ripple formation. Bradley-Harper (B-H) theory and its extensions were invoked to explain ion erosion-induced ripple formation due to off-normal ion bombardment and its coarsening [22, 23]. Following these theories, there are reports which show that Linsitinib concentration although ripples are more or less periodic in nature in the linear regime, with increasing time, it may change to a sawtooth-like morphology [9, 12, 13]. This type of transition from ripples to sawtooth or faceted structures was mentioned by Makeev and Barabasi for small surface gradients [24, 25] which was later generalized by Carter at intermediate ion energies (few tens of kiloelectron volts) for all surface gradients [26].

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