Graphene and Semiconductors

Biography

Biography: Gilbert chachine

Abstract

Structure determination of crystal lattice parameters and orientation with high precision is rather straightforward for bulk 3D-materials. X-ray diffraction proved especially powerful in this respect across the years. On the contrary, structural determination of 2D crystals with the help of x-rays is more demanding. So far, exploiting interferences between a crystalline substrate and graphene, it was possible to accurately determine the lattice parameter of graphene, averaged across the ~1cm² surface of a sample^[1,2]. Such studies are however restricted to graphene samples of macroscopically uniform crystalline orientation. However most graphene samples of relevance for potential applications (micro-electronics, telecom, displays) exhibit inhomogeneities, as they are composed of single-crystal grains (~10µm), each having different crystalline orientation and strain. Finely characterizing such structural features requires to probe suspended graphene with the help of nano-shaped beams.Using, instead of electron beams, nanofocused X-rays, we managed to conduct simultaneously Small and Wide Angle X-ray Scattering (SAXS/WAXS) characterizations with high resolution in reciprocal space and an unprecedented resolution of 200nm in real space, Accordingly we were able to map the structural variations in two- dimensions, revealing in this way strain maps for the suspended few-layer graphene membrane and the morphological features at the edges of the flakes, where it forms scrolls with a typical length of the order of 10µm and a diameter of the order of 10nm.  The orientation of the nanoscrollls could for instance be resolved.Our complementary analysis with spatially-resolved Raman spectroscopy provides the unique opportunity to unambiguously determine the Grüneisen parameters of graphene, linking the deformation to the energy of its vibration modes, without any particular assumption.These experiments pave the way to advanced in-situ experiments and for exploring 2D crystals and their phase transitionsusing synchrotron radiation especially with the future upgrade programs in the European Synchrotron for outstanding expected brilliance.