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View article: Erratum: Bending Rigidity of 2D Silica [Phys. Rev. Lett. <b>120</b>, 226101 (2018)]
Erratum: Bending Rigidity of 2D Silica [Phys. Rev. Lett. <b>120</b>, 226101 (2018)] Open
This corrects the article DOI: 10.1103/PhysRevLett.120.226101.
View article: Nanometer-Resolution Mask Lithography with Matter Waves: Near-Field Binary Holography
Nanometer-Resolution Mask Lithography with Matter Waves: Near-Field Binary Holography Open
Mask-based pattern generation is a crucial step in microchip production. The next-generation extreme-ultraviolet- (EUV) lithography instruments with a wavelength of 13.5 nm are currently under development. In principle, this should allow p…
View article: Wave scattering from two-dimensional self-affine Dirichlet and Neumann surfaces and its application to the retrieval of self-affine parameters
Wave scattering from two-dimensional self-affine Dirichlet and Neumann surfaces and its application to the retrieval of self-affine parameters Open
Wave scattering from two-dimensional self-affine Dirichlet and Neumann\nsurfaces is studied for the purpose of using the intensity scattered from them\nto obtain the Hurst exponent and topothesy that characterize the self-affine\nroughness…
View article: Bending Rigidity of 2D Silica
Bending Rigidity of 2D Silica Open
A chemically stable bilayers of SiO_{2} (2D silica) is a new, wide band gap 2D material. Up till now graphene has been the only 2D material where the bending rigidity has been measured. Here we present inelastic helium atom scattering data…
View article: Optimal Design of Grid-Based Binary Holograms for Matter-Wave Lithography
Optimal Design of Grid-Based Binary Holograms for Matter-Wave Lithography Open
Grid based binary holography (GBH) is an attractive method for patterning with light or matter waves. It is an approximate technique in which different holographic masks can be used to produce similar patterns. Here we present an optimal d…
View article: Neutral-helium-atom diffraction from a micron-scale periodic structure: Photonic-crystal-membrane characterization
Neutral-helium-atom diffraction from a micron-scale periodic structure: Photonic-crystal-membrane characterization Open
Surface scattering of neutral helium beams created by supersonic expansion is\nan established technique for measuring structural and dynamical properties of\nsurfaces on the atomic scale. Helium beams have also been used in Fraunhofer\nand…