The
oxidation and corrosion of copper are fundamental issues studied
for many decades due to their ubiquitous and transversal impact. However,
the oxidation of copper used as catalyst for graphene synthesis has
opened a singular problem not yet solved. Contradictory results are
reported about the protecting or enhancing role of graphene in copper
oxidation. We study short- and long-term oxidation of copper with
different characteristics, such as oxygen content and morphology,
with and without graphene, and in polycrystalline copper foils and
almost totally textured (100) and (111) copper films on MgO and sapphire
substrates, respectively. We propose a mechanism to explain the enhanced
oxidation of polycrystalline
copper originated by oxygen encapsulated by the graphene impermeable
layer during graphene growth. The initial oxygen content and the existence
of grain boundaries are the main factors that determine the relevance
of this process. Graphene is shown to prevent oxidation from the atmosphere
for any of the copper substrates but also promotes slow oxidation
derived by the release of out-of-equilibrium encapsulated oxygen.
The formation of bubbles after several months evidence this slow release.
The occluded oxygen in graphene covered copper is demonstrated by
comparing the oxygen to copper ratio at different depths using hard
X-ray photoelectron spectroscopy for samples with and without graphene.
Understanding the interaction between graphene and its supporting substrate is of paramount importance for the development of graphene based applications. In this work the interplay of the technologically relevant graphene-Cu system is investigated in detail as a function of substrate grain orientation in Cu polycrystalline foils. While (100) and (111) Cu grains show the well-known graphene-enhanced oxidation, (110) grains present a superior oxidation resistance compared to uncovered Cu and an anomalous shift of its graphene 2D Raman band which cannot be explained by the known effects of strain and doping. These results are interpreted in terms of a weak graphene-Cu coupling at the (110) grains, and show that graphene can actually be used as anticorrosion coating, contrary to previously reported. The anomalous shift is suggested to be the result of an enhanced outer Raman scattering process which surpasses the usually dominant inner process. Since Raman spectroscopy is widely used as first and main characterization tool of graphene, the existence of an anomalous shift on its 2D band not only challenges the current theory of Raman scattering in graphene, but also has profound implications from an experimental point of view.
The detection, identification, and quantification of different types of molecules and the optical imaging of, for example, cellular processes are important challenges. Here, we present how interference-enhanced Raman scattering (IERS) in adequately designed heterostructures can provide amplification factors relevant for both detection and imaging. Calculations demonstrate that the key factor is maximizing the absolute value of the refractive indices' difference between dielectric and metal layers. Accordingly, Si/Al/AlO/graphene heterostructures have been fabricated by optimizing the thickness and roughness and reaching enhancement values up to 700 for 488 nm excitation. The deviation from the calculated enhancement, 1200, is mainly due to reflectivity losses and roughness of the Al layer. The IERS platforms are also demonstrated to improve significantly the quality of white light images of graphene and are foreseen to be adequate to reveal the morphology of 2D and biological materials. A graphene top layer is adequate for most organic molecule deposition and often quenches possible fluorescence, permitting Raman signal detection, which, for a rhodamine 6G (R6G) monolayer, presents a gain of 400. Without graphene, the nonquenched R6G fluorescence is similarly amplified. The wavelength dependence of the involved refractive indices predicts much higher amplification (around 10) for NIR excitation. These interference platforms can therefore be used to gain contrast and intensity in white light, Raman, and fluorescence imaging. We also demonstrate that surface-enhanced Raman scattering and IERS amplifications can be efficiently combined, leading to a gain of >10 (at 488 nm) by depositing a Ag nanostructured transparent film on the IERS platform. When the plasmonic structures deposited on the IERS platforms are optimized, single-molecule detection can be actively envisaged.
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