René Feder scite author profile

Low energy ion beam pattern formation on Si with simultaneous co-deposition of Ag, Pd, Pb, Ir, Fe or C impurities was investigated by in situ scanning tunneling microscopy as well as ex situ atomic force microscopy, scanning electron microscopy, transmission electron microscopy and Rutherford backscattering spectrometry. The impurities were supplied by sputter deposition. Additional insight into the mechanism of pattern formation was obtained by more controlled supply through e-beam evaporation. For the situations investigated, the ability of the impurity to react with Si, i.e. to form a silicide, appears to be a necessary, but not a sufficient condition for pattern formation. Comparing the effects of impurities with similar mass and nuclear charge, the collision kinetics is shown to be not of primary importance for pattern formation. To understand the observed phenomena, it is necessary to assume a bi-directional coupling of composition and height fluctuations. This coupling gives rise to a sensitive dependence of the final morphology on the conditions of impurity supply. Because of this history dependence, the final morphology cannot be uniquely characterized by a steady state impurity concentration.

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Ion beam sputtering of Ag – Angular and energetic distributions of sputtered and scattered particles

Feder

Bundesmann

Neumann

et al. 2013

Nuclear Instruments and Methods in Physics Research Section B:

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Broadband Enhanced Chirality with Tunable Response in Hybrid Plasmonic Helical Metamaterials

Kılıç

Hilfiker

Ruder

et al. 2021

Adv Funct Materials

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Designing broadband enhanced chirality is of strong interest to the emerging fields of chiral chemistry and sensing, or to control the spin orbital momentum of photons in recently introduced nanophotonic chiral quantum and classical optical applications. However, chiral light‐matter interactions have an extremely weak nature, are difficult to control and enhance, and cannot be made tunable or broadband. In addition, planar ultrathin nanophotonic structures to achieve strong, broadband, and tunable chirality at the technologically important visible to ultraviolet spectrum still remain elusive. Here, these important problems are tackled by experimentally demonstrating and theoretically verifying spectrally tunable, extremely large, and broadband chiroptical response by nanohelical metamaterials. The reported new designs of all‐dielectric and dielectric‐metallic (hybrid) plasmonic metamaterials permit the largest and broadest ever measured chiral Kuhn's dissymmetry factor achieved by a large‐scale nanophotonic structure. In addition, the strong circular dichroism of the presented bottom‐up fabricated optical metamaterials can be tuned by varying their dimensions and proportions between their dielectric and plasmonic helical subsections. The currently demonstrated ultrathin optical metamaterials are expected to provide a substantial boost to the developing field of chiroptics leading to significantly enhanced and broadband chiral light‐matter interactions at the nanoscale.

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Systematic investigations of low energy Ar ion beam sputtering of Si and Ag

Feder

Frost

Neumann

et al. 2013

Nuclear Instruments and Methods in Physics Research Section B:

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Ion beam sputter deposition of Ag films: Influence of process parameters on electrical and optical properties, and average grain sizes

et al. 2014

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René Feder

Silicide induced ion beam patterning of Si(001)

Ion beam sputtering of Ag – Angular and energetic distributions of sputtered and scattered particles

Broadband Enhanced Chirality with Tunable Response in Hybrid Plasmonic Helical Metamaterials

Systematic investigations of low energy Ar ion beam sputtering of Si and Ag

Ion beam sputter deposition of Ag films: Influence of process parameters on electrical and optical properties, and average grain sizes

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