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77 results on '"Blumtritt, H."'

1. Structural and electronic properties of epitaxial multilayer h-BN on Ni(111) for spintronics applications

Author

Tonkikh, A. A., Voloshina, E. N., Werner, P., Blumtritt, H., Senkovskiy, B., Güntherodt, G., Parkin, S. S. P., and Dedkov, Yu. S.

Subjects
Condensed Matter - Materials Science
Abstract

Hexagonal boron nitride (h-BN) is a promising material for implementation in spintronics due to a large band gap, low spin-orbit coupling, and a small lattice mismatch to graphene and to close-packed surfaces of fcc-Ni(111) and hcp-Co(0001). Epitaxial deposition of h-BN on ferromagnetic metals is aimed at small interface scattering of charge and spin carriers. We report on the controlled growth of h-BN/Ni(111) by means of molecular beam epitaxy (MBE). Structural and electronic properties of this system are investigated using cross-section transmission electron microscopy (TEM) and electron spectroscopies which confirm good agreement with the properties of bulk h-BN. The latter are also corroborated by density functional theory (DFT) calculations, revealing that the first h-BN layer at the interface to Ni is metallic. Our investigations demonstrate that MBE is a promising, versatile alternative to both the exfoliation approach and chemical vapour deposition of h-BN., Comment: text, 4 figures, and supplementary info

Published
2015
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6. Defect-induced breakdown in multicrystalline silicon solar cells

Author

Breitenstein, O., Bauer, J., Wagner, J.-M., Zakharov, N., Blumtritt, H., Lotnyk, A., Kasemann, M., Kwapil, W., and Warta, W.

Subjects
Solar batteries -- Innovations, Solar cells -- Innovations, Silicon -- Electric properties, Electroluminescence -- Analysis, Voltage -- Measurement, Simulation methods -- Usage, Business, Electronics, Electronics and electrical industries
Published
2010

10. Localization and characterization of annealing-induced shunts in Ni-plated monocrystalline silicon solar cells

Author

Büchler, A., Kluska, S., Kasemann, M., Breitwieser, M., Kwapil, W., Hähnel, A., Blumtritt, H., Hopman, S., Glatthaar, M., and Publica

Subjects
Silicium-Photovoltaik, Silicide, Messtechnik und Produktionskontrolle, Emitter, ReBEL, Solarzellen - Entwicklung und Charakterisierung, Pilotherstellung von industrienahen Solarzellen
Abstract

The adhesion of Ni-Cu-plated contacts requires annealing, which can lead to an electrical degradation of the solar cell. A combination of optical imaging methods and electron microscopical cross-section analysis was used to investigate the annealing-induced shunts on monocrystalline solar cells. The results show that Ni spikes cause the lowering of the pseudo fill factor and reveal that these nonlinear shunts show the same behavior as recombination active breakdown sites on multicrystalline silicon solar cells, including radiation of visible light while breakdown. Using reverse biased electroluminescence set-up the shunts could be localized in top view with µm size lateral resolution. Subsequently, a cross-section was prepared on a radiative breakdown spot. Advanced electron microscopic investigations reveal defect structures featuring nickel precipitates on the position of the light source.

Published
2014

13. Avalanche breakdown in multicrystalline solar cells due to preferred phosphorous diffusion at extended defects

Author

Bauer, J., Lausch, D., Blumtritt, H., Zakharov, N., Breitenstein, O., and Publica

Abstract

Multicrystalline solar cells break down strongly at reverse voltages well below the theoretical limit. Previous explanations were based on assuming a constant depth of the junction below the surface. In this work, preferred phosphorous diffusion at special line defects in grain boundaries is shown to lead to spikes in the p-n junctions even below flat surfaces. The curvature radii of the spherical p-n junction bending are measured by electron beam-induced current to be in the range of 300-500nm, leading to the observed type III avalanche breakdown voltages.

Published
2013

14. Electron microscope verification of prebreakdown-inducing alpha-FeSi2 needles in multicrystalline silicon solar cells

Author

Hähnel, A., Bauer, J., Blumtritt, H., Breitenstein, O., Lausch, D., Kwapil, W., and Publica

Abstract

It had been shown already earlier by X-ray microanalysis that, in positions of defect-induced junction breakdown in industrial multicrystalline (mc) silicon solar cells, iron-containing precipitates may exist. However, the nature of these precipitates was unknown so far. Here, in such positions, scanning transmission electron microscopy was performed after defect-controlled focused ion beam preparation. First of all, the defect site was localized by microscopic reverse-bias electroluminescence imaging. The high accuracy of following FIB target preparation (

Published
2013

15. A Novel Origin of Avalanche Breakdown in Multicrystalline Silicon Solar Cells

Author

Bauer, J., Lausch, D., Blumtritt, H., Zakharov, N., and Breitenstein, O.

Subjects
Silicon Solar Cell Characterization and Modelling, Wafer-Based Silicon Solar Cells and Materials Technology
Abstract

27th European Photovoltaic Solar Energy Conference and Exhibition; 857-860, The root causes of breakdown of multicrystalline silicon solar cell well below the theoretical limit are investigated in this contribution. The main focus of this paper is on avalanche, or so called type-3, breakdown sites in alkaline texturized solar cells. However, the similarities and differences of the same breakdown type in isotextured solar cells are described as well. Using EBIC charge collecting contrast of p-n junctions at FIB prepared cross sections it is found that possible enhanced phosphorous diffusion at certain line defects in the material leads to spikes of the p-n junction despite of a flat surface of alkaline textured solar cells. Avalanche breakdown occurs at these spikes similar to the avalanche breakdown at etch pits in isotextured solar cells, but at slightly higher absolute reverse voltages as compared to the latter ones. It is assumed that the differences of the breakdown onset voltages are due to the slightly different p-n junction curvature shapes in alkaline and isotextured solar cells.

Published
2012
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16. TEM Investigations on an Iron Silicide Particle Inducing Type-2 Breakdown in mc-Si Solar Cells

Author

Bauer, J., Hähnel, A., Blumtritt, H., Lausch, D., Kwapil, W., and Breitenstein, O.

Subjects
Silicon Solar Cell Characterization and Modelling, Wafer-Based Silicon Solar Cells and Materials Technology
Abstract

27th European Photovoltaic Solar Energy Conference and Exhibition; 1246-1250, Investigations of electrical breakdown in multicrystalline silicon solar cells in the last couple of years revealed different breakdown mechanisms. One breakdown type is found to occur dominantly at highly recombinative defect structures and is called type-2 breakdown. It was reported that metal precipitates, containing mainly iron, play a major role for the formation of such breakdown sites. In this contribution type-2 breakdown sites were localized with high precision using micro reverse-bias electroluminescence, focused ion beam preparation, and different electron microscopy methods. It can be shown that type-2 breakdown sites found here are caused by rod-like a-FeSi2 precipitates. These precipitates are located at large angle grain boundaries and can be assigned to dislocation lines. Taking into account the quasi metallic behavior of a-FeSi2 rods, their position directly at the p-n junction, and their size, a model of the breakdown mechanism based on a Schottky junction between the p-doped solar cell’s base and the metal precipitate is proposed.

Published
2012
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17. SiC Precipitates in Block-Cast Multicrystalline Silicon: A TEM Characterization

Author

Lotnyk, A., Bauer, J., Breitenstein, O., and Blumtritt, H.

Subjects
Mono- and Multicrystalline Silicon Cells and Materials, Processing Technology of, Wafer-Based Silicon Solar Cells and Materials Technology
Abstract

23rd European Photovoltaic Solar Energy Conference and Exhibition, 1-5 September 2008, Valencia, Spain; 1406-1409, The microstructure of SiC particles and SiC filament-type precipitates found in block-cast multicrystalline Si was studied in detail by transmission electron microscopy (TEM). TEM investigations showed that the SiC particles are monocrystalline and the SiC filaments are microcrystalline. Both types of precipitates consist of cubic SiC (3C polytype). However, a high density of planar defects was found in the filaments. High-resolution TEM analysis of the interface between SiC filaments and Si matrix revealed that the interface is rough and very wavy. SiC filaments do not show a special orientation relationship with respect to the Si matrix. The growth mechanisms of SiC precipitates are discussed. The influence of SiC inclusions in terms of device performance is also considered.

Published
2008
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35. Electron microscope verification of prebreakdown-inducing α-FeSi2 needles in multicrystalline silicon solar cells.

Author

Hähnel, A., Bauer, J., Blumtritt, H., Breitenstein, O., Lausch, D., and Kwapil, W.

Subjects
SOLAR cells, MICROCHEMISTRY, SILICON, ELECTRON microscopes, SCANNING electron microscopes, CRYSTAL grain boundaries, ELECTRON diffraction
Abstract

It had been shown already earlier by X-ray microanalysis that, in positions of defect-induced junction breakdown in industrial multicrystalline (mc) silicon solar cells, iron-containing precipitates may exist. However, the nature of these precipitates was unknown so far. Here, in such positions, scanning transmission electron microscopy was performed after defect-controlled focused ion beam preparation. First of all, the defect site was localized by microscopic reverse-bias electroluminescence imaging. The high accuracy of following FIB target preparation (<0.1 μm necessary) was obtained by both, electron beam-induced current imaging and secondary electron material contrast observation during the slice-by-slice milling of the TEM specimen. By nano-beam electron diffraction (NBED) and energy dispersive spectroscopy, the iron-containing precipitates were identified as α-type FeSi2 needles, about 30 nm in diameter and several μm in length. The FeSi2 needles show preferential orientation relationships to the silicon matrix and are located in terraced large-angle grain boundaries. Elaborate nano-beam electron diffraction investigation of the FeSi2 revealed orientation relationships of the precipitate to the silicon, which confirm earlier investigations on monocrystalline material. A model explaining the defect-induced breakdown mechanism due to rod-like α-FeSi2 precipitates is presented. [ABSTRACT FROM AUTHOR]

Published
2013
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37. Ferroelectric domain structure of (CH3NH3)5Bi2Brll single crystals

Author

Połomska, M., Szczesniak, L., Jakubas, R., Meyer, K. -P., and Blumtritt, H.

Abstract

Ferroelectric domain structure of (CH3, NH3)5 Bi2 Br11 single crystals was revealed using nematic liquid crystal decoration and scanning electron microscopy. The domain boundaries observed on the c-surface of the crystal were found to be parallel to the b-orthorhombic axis and this direction was found to be an easy direction of domain growth.

Published
1989
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46. Organic crystal lattices in the axial filament of silica spicules of Demospongiae.

Author

Werner P, Blumtritt H, and Natalio F

Subjects
Animals, Crystallization, Finite Element Analysis, Microscopy, Electron, Microscopy, Electron, Transmission, Morphogenesis, Organic Chemicals chemistry, Porifera chemistry, Porifera growth & development, Porifera ultrastructure, Suberites ultrastructure, Porifera anatomy & histology, Silicon Dioxide chemistry
Abstract

The skeletal system of Demospongiae consists of siliceous spicules, which are composed of an axial channel containing an organic axial filament (AF) surrounded by a compact layer of hydrated amorphous silica. Here we report the ultrastructural investigations of the AF of siliceous spicules from two Demospongiae: Suberites domuncula and Tethya aurantium. Electron microscopy, electron diffraction and elemental mapping analyses on both longitudinal and transversal cross-sections yield that spicules's AF consist of a three-dimensional crystal lattice of six-fold symmetry. Its structure, which is the result of a biological growth process, is a crystalline assembly characterized by a lattice of organic cages (periodicity in the range of 6nm) filled with enzymatically-produced silica. In general, the six-fold lattice symmetry is reflected by the morphology of the AF, which is characterized by six-fold facets. This seems to be the result of a lattice energy minimization process similar to the situation found during the growth of inorganic crystals. Our structural exploitation of three-dimensional organic lattices generated by biological systems is expected to contribute for explaining the relation between axial filament's ultrastructure and spicule's ultimate morphology., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published
2017
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47. Weyl Semimetals as Hydrogen Evolution Catalysts.

Author

Rajamathi CR, Gupta U, Kumar N, Yang H, Sun Y, Süß V, Shekhar C, Schmidt M, Blumtritt H, Werner P, Yan B, Parkin S, Felser C, and Rao CNR

Abstract

The search for highly efficient and low-cost catalysts is one of the main driving forces in catalytic chemistry. Current strategies for the catalyst design focus on increasing the number and activity of local catalytic sites, such as the edge sites of molybdenum disulfides in the hydrogen evolution reaction (HER). Here, the study proposes and demonstrates a different principle that goes beyond local site optimization by utilizing topological electronic states to spur catalytic activity. For HER, excellent catalysts have been found among the transition-metal monopnictides-NbP, TaP, NbAs, and TaAs-which are recently discovered to be topological Weyl semimetals. Here the study shows that the combination of robust topological surface states and large room temperature carrier mobility, both of which originate from bulk Dirac bands of the Weyl semimetal, is a recipe for high activity HER catalysts. This approach has the potential to go beyond graphene based composite photocatalysts where graphene simply provides a high mobility medium without any active catalytic sites that have been found in these topological materials. Thus, the work provides a guiding principle for the discovery of novel catalysts from the emerging field of topological materials., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2017
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48. Nano-channels in the spider fang for the transport of Zn ions to cross-link His-rich proteins pre-deposited in the cuticle matrix.

Author

Politi Y, Pippel E, Licuco-Massouh AC, Bertinetti L, Blumtritt H, Barth FG, and Fratzl P

Subjects
Animals, Chitin chemistry, Cross-Linking Reagents chemistry, Histidine chemistry, Insulin chemistry, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Molting physiology, Nanotechnology, Protein Binding, Serum Albumin, Bovine chemistry, Synchrotrons, X-Ray Absorption Spectroscopy, Animal Structures physiology, Arthropod Proteins physiology, Ions, Spiders physiology, Zinc chemistry
Abstract

We identify the presence of multiple vascular channels within the spider fang. These channels seem to serve the transport of zinc to the tip of the fang to cross-link the protein matrix by binding to histidine residues. According to amino acid and elemental analysis of fangs extracted shortly after ecdysis, His-rich proteins are deposited before Zn is incorporated into the cuticle. Microscopic and spectroscopic investigations in the electron microscope and synchrotron radiation experiments suggest that Zn ions are transported through these channels in a liable (yet unidentified) form, and then form stable complexes upon His binding. The resulting cross-linking through the Zn-His complexes is conferring hardness to the fang. Our observations of nano-channels serving the Zn-transport within the His-rich protein matrix of the fibre reinforced spider fang may also support recent bio-inspired attempts to design artificial polymeric vascular materials for self-healing and in-situ curing., (Copyright © 2016 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2017
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49. Electron microscope analyses of the bio-silica basal spicule from the Monorhaphis chuni sponge.

Author

Werner P, Blumtritt H, Zlotnikov I, Graff A, Dauphin Y, and Fratzl P

Subjects
Animals, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Spectrometry, X-Ray Emission, Porifera ultrastructure, Silicon Dioxide chemistry
Abstract

We report on a structural analysis of several basal spicules of the deep-sea silica sponge Monorhaphis chuni by electron microscope techniques supported by a precise focused ion beam (FIB) target preparation. To get a deeper understanding of the spicules length growth, we concentrated our investigation onto the apical segments of two selected spicules with apparently different growth states and studied in detail permanent and temporary growth structures in the central compact silica axial cylinder (AC) as well as the structure of the organic axial filament (AF) in its center. The new findings concern the following morphology features: (i) at the tip we could identify thin silica layers, which overgrow as a tongue-like feature the front face of the AC and completely fuse during the subsequent growth state. This basically differs from the radial growth of the surrounding lamellar zone of the spicules made of alternating silica lamellae and organic interlayers. (ii) A newly detected disturbed cylindrical zone in the central region of the AC (diameter about 30 μm) contains vertical and horizontal cavities, channels and agglomerates, which can be interpreted as permanent leftover of a formerly open axial channel, later filled by silica. (iii) The AF consists of a three-dimensional crystal-like arrangement of organic molecules and amorphous silica surrounding these molecules. Similar to an inorganic crystal, this encased protein crystal is typified by crystallographic directions, lattice planes and surface steps. The 〈001〉 growth direction is especially favored, thereby scaffolding the axial cylinders growth and consequently the spicules' morphology., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published
2015
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50. A perfectly periodic three-dimensional protein/silica mesoporous structure produced by an organism.

Author

Zlotnikov I, Werner P, Blumtritt H, Graff A, Dauphin Y, Zolotoyabko E, and Fratzl P

Subjects
Animals, Microscopy, Electron, Scanning Transmission, Microscopy, Electron, Transmission, Models, Chemical, Spectrum Analysis, X-Ray Diffraction, X-Rays, Porifera chemistry, Porifera ultrastructure, Proteins chemistry, Silicon Dioxide chemistry
Abstract

The discovery of perfectly ordered 3D mesoporous protein/silica structure in the axial filament of the marine sponge Monorhaphis chuni is reported. The structure belongs to body-centered tetragonal symmetry system (a=9.88 nm, c=10.83 nm) and comprises interconnecting lattices of protein and silica, templated by the self-assembled, enzymatically active protein-silicatein, whose primary function is the precipitation of silica., (© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2014
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