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107. Effect of crystal orientation on the hardness and strength of piezoelectric LiNbO3 substrates for microelectronic applications.

Author

Gruber, M., Leitner, A., Kiener, D., Supancic, P., and Bermejo, R.

Subjects
*CRYSTAL orientation, *ACOUSTIC surface waves, *SPEED of sound, *HARDNESS, *LITHIUM niobate, *NANOINDENTATION
Abstract

[Display omitted] • Hardness anisotropy associated with crystal orientation governs surface damage morphology in LiNbO 3. • A 20% difference in hardness can double the characteristic strength of LiNbO 3. • Tailored high Young's modulus surface planes of LiNbO 3 can significantly increase its characteristic strength. Piezoelectric single crystalline materials are paramount for high-speed data transfer in 5G technologies. The functionality of the end-devices demands temperature independent frequency filtering and high surface acoustic wave velocities, which are associated with the orientation dependent thermo-physical properties of the piezoelectric substrate material. Single crystalline Lithium Niobate (LiNbO 3), cut in particular directions, has proven to have outstanding functional properties, yet its brittle character along with the highly anisotropic mechanical properties may limit its use in demanding applications. In this study, the effect of crystal orientation on hardness and on mechanical strength is demonstrated by comparing nanoindentation results and finite element analysis supported biaxial strength experiments for two LiNbO 3 samples with different orientation. It is demonstrated that the crystal anisotropy leads to differences in hardness up to ∼ 20% between both orientations, with the characteristic strength being double in the harder direction. The observed correlation is rationalized based on the effect of surface finish and distinct sub-surface damage in the corresponding crystal orientations. Additional strength measurements on nano-scratched samples revealed a significantly higher remaining strength for the harder orientation due to less (sub-) surface damage. These findings can be exploited in future design of single crystalline substrate materials with higher reliability. [ABSTRACT FROM AUTHOR]

Published
2022
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108. High-speed nanoindentation mapping of organic matter-rich rocks: A critical evaluation by correlative imaging and machine learning data analysis.

Author

Vranjes-Wessely, S., Misch, D., Kiener, D., Cordill, M.J., Frese, N., Beyer, A., Horsfield, B., Wang, C., and Sachsenhofer, R.F.

Subjects
*MACHINE learning, *NANOINDENTATION, *DATA analysis, *INHOMOGENEOUS materials, *ELASTIC modulus, *MECHANICAL properties of condensed matter, *K-means clustering
Abstract

Nanoindentation is a valuable tool, which enables insights into the material properties of natural, highly inhomogeneous composite materials such as shales and organic matter-rich rocks. However, the inherent complexity of these rocks and its constituents complicates the extraction of representative material parameters such as the reduced elastic modulus (E r) and hardness (H) for organic matter (OM) via nanoindentation. The present study aims to extract the representative H and E r values for OM within an over-mature sample set (1.33–2.23%Rr) from the Chinese Songliao Basin and evaluate influencing factors of the resulting parameters. This was realized by means of high-speed nanoindentation mapping in combination with comprehensive optical and high resolution-imaging methods. The average E r and H values for the different particles range from 3.86 ± 0.17 to 7.52 ± 3.80 GPa and from 0.36 ± 0.02 to 0.64 ± 0.09 GPa, respectively. The results were subsequently processed by the unsupervised machine learning algorithm k -means clustering in order to evaluate representative E r and H results. The post-processing suggests that inherent heterogeneity of OM is responsible for considerable data scattering. In fact, surrounding, underlying and inherent mineral matter lead to confinement effects and enhanced E r values, whereas cracks and pores are responsible for a lowered stiffness. Adjusted for these influencing factors, a declining trend with increasing maturity (up to 1.96%Rr) could be observed for E r , with average values calculated from representative clusters ranging from 5.88 ± 0.37 down to 4.07 ± 0.32 GPa. E r slightly increases again between 2.00 and 2.23%Rr (up to 4.85 ± 0.35 GPa). No clear relationship of H with thermal maturity was observed. The enhanced accuracy archived by a large data set facilitated machine learning approach not only improves further modelling attempts but also allows insights of impacting geological processes on the material parameter and general understanding of mechanical behavior of OM in rock formations. Thus, the presented multimethod approach promotes a fast and reliable assessment of representative material parameters from organic rock constituents. • Extracting representative mechanical parameters from organic matter in rocks. • Correlative imaging facilitated by femtosecond laser-machined grid. • Data processing by means of unsupervised machine learning (k -means clustering). • Revealing various impacting factors on material behavior of organic matter. [ABSTRACT FROM AUTHOR]

Published
2021
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109. Strength determination for rough substrate-coating interfaces with three-dimensional defect structure.

Author

Klünsner, T., Krobath, M., Konetschnik, R., Tritremmel, C., Maier-Kiener, V., Samardzic, D., Ecker, W., Czettl, C., Mitterer, C., and Kiener, D.

Subjects
*MATERIALS testing, *FOCUSED ion beams, *BRITANNIA metal, *SCANNING electron microscopes, *STRESS fractures (Orthopedics), *SURFACE coatings, *CERAMIC coating
Abstract

Quantitative information on the strength of interfaces between thin ceramic coatings and their substrates is crucial when aiming to understand their failure behavior. Many technically relevant substrate-coating interfaces are not ideally planar, but rather rough and contain stress concentrators forming three-dimensional defect structures. An example for such a realistic case, a polycrystalline diamond coating that partially penetrates voids and cavities in its Co binder-depleted WC-Co hard metal substrate, was investigated within the current work with respect to its unknown interface strength behavior. Special focus was laid on the influence of the applied load direction on the observed fracture behavior. Micromechanical specimens were produced via focused ion beam milling as geometry variants of a micro shear compression specimen with their loaded areas' relative inclination towards the substrate-coating interface varied from 0° to 88°. Specimen loading was performed until fracture with a flat punch indenter in a scanning electron microscope. The recorded fracture loads were associated with the spatial stress distributions at fracture via finite element-based analysis. A plateau of the determined maximum principal stress triggering fracture in the ceramic-ceramic interfaces was found for inclination angles ≥45°. This plateau value was identified as the interface strength by observation of the crack path at the substrate-coating interface via scanning electron microscopy and analysis of the effectively loaded interface area values. The presented novel material testing technique gives first and previously not accessible insight into the fracture behavior of rough substrate-coating interfaces with complex defect structure. [Display omitted] • Substrate-coating interface strength determined for CVD diamond-coated hard metal by new materials testing technique. • First-time strength determination for rough substrate-coating interfaces with three-dimensional defect structure. • Specimen geometry variation facilitates previously not possible investigation of interface defect texture. [ABSTRACT FROM AUTHOR]

Published
2023
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110. Strain Field Around Individual Dislocations Controls Failure.

Author

Gammer C, Issa I, Minor AM, Ritchie RO, and Kiener D

Abstract

Understanding material failure on a fundamental level is a key aspect in the design of robust structural materials, especially for metals and alloys capable to undergo plastic deformation. In the last decade, significant progress is made in quantifying the stresses associated with failure in both experiments and simulations. Nonetheless, the processes occurring on the most essential level of individual dislocations that govern semi-brittle and ductile fracture are still experimentally not accessible, limiting the failure prediction capabilities. Therefore, in the present work, a one-of-a-kind nanoscale fracture experiment is conducted on a single crystalline Cr bending beam in situ in the transmission electron microscope and for the first time quantify the transient strains around individual dislocations, as well as of the whole dislocation network during crack opening. The results reveal the importance of both pre-existing and newly emitted dislocations for crack-tip shielding via their intrinsic strain field and provide guidelines to design more damage tolerant materials., (© 2024 The Authors. Small Methods published by Wiley‐VCH GmbH.)

Published
2024
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111. Unraveling the orientation-dependent mechanics of dental enamel in the red-necked wallaby.

Author

Wilmers J, Wurmshuber M, Gescher C, Graupp CM, Kiener D, and Bargmann S

Subjects
Animals, Biomechanical Phenomena, Stress, Mechanical, Dental Enamel chemistry, Finite Element Analysis, Macropodidae physiology
Abstract

Dental enamels of different species exhibit a wide variety of microstructural patterns that are attractive to mimic in bioinspired composites to simultaneously achieve high stiffness and superior toughness. Non-human enamel types, however, have not yet received the deserved attention and their mechanical behaviour is largely unknown. Using nanoindentation tests and finite element modelling, we investigate the mechanical behaviour of Macropus rufogriseus enamel, revealing a dominating influence of the microstructure on the effective mechanical behaviour and allowing insight into structural dependencies. We find a shallow gradient in stiffness and low degree of anisotropy over the enamel thickness that is attributed to the orientation and size of microstructural features. Most notably, M. rufogriseus's modified radial enamel has a far simpler structural pattern than other species', but achieves great property amplification. It is therefore a very promising template for biomimetic design. STATEMENT OF SIGNIFICANCE: The diversity of dental enamel structures in different species is well documented, but the mechanical behaviour of non-human enamel types is largely unknown. In this work, we investigate the microstructure and structure-dependent mechanical properties of marsupial enamel by nanoindentation and finite element simulations. Combining these methods gives valuable insights into the performance of modified radial enamel structures. Their stiffness and toughness stems from a unique structural design that is far less complex than well-studied human enamel types, which makes it a uniquely suitable template for biomimetic design., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published
2024
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112. Mapping the composite nature of clay matrix in mudstones: integrated micromechanics profiling by high-throughput nanoindentation and data analysis.

Author

Shi X, Misch D, Zak S, Cordill M, and Kiener D

Abstract

Mudstones and shales serve as natural barrier rocks in various geoenergy applications. Although many studies have investigated their mechanical properties, characterizing these parameters at the microscale remains challenging due to their fine-grained nature and susceptibility to microstructural damage introduced during sample preparation. This study aims to investigate the micromechanical properties of clay matrix composite in mudstones by combining high-speed nanoindentation mapping and machine learning data analysis. The nanoindentation approach effectively captured the heterogeneity in high-resolution mechanical property maps. Utilizing machine learning-based k -means clustering, the mechanical characteristics of matrix clay, brittle minerals, as well as measurements on grain boundaries and structural discontinuities (e.g., cracks) were successfully distinguished. The classification results were validated through correlation with broad ion beam-scanning electron microscopy images. The resulting average reduced elastic modulus ( E r ) and hardness ( H ) values for the clay matrix were determined to be 16.2 ± 6.2 and 0.5 ± 0.5 GPa, respectively, showing consistency across different test settings and indenter tips. Furthermore, the sensitivity of indentation measurements to various factors was investigated, revealing limited sensitivity to indentation depth and tip geometry (when comparing Cube corner and Berkovich tip in a small range of indentation depth variations), but decreased stability at lower loading rates. Box counting and bootstrapping methods were applied to assess the representativeness of parameters determined for the clay matrix. A relatively small dataset (indentation number = 60) is needed to achieve representativeness, while the main challenges is to cover a representative mapping area for clay matrix characterization. Overall, this study demonstrates the feasibility of high-speed nanoindentation mapping combined with data analysis for micromechanical characterization of the clay matrix in mudstones, paving the way for efficient analysis of similar fine-grained sedimentary rocks., Supplementary Information: The online version contains supplementary material available at 10.1007/s40948-024-00864-9., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published
2024
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114. Limpet teeth microstructure unites auxeticity with extreme strength and high stiffness.

Author

Oh SH, Kim JK, Liu Y, Wurmshuber M, Peng XL, Seo J, Jeong J, Wang Z, Wilmers J, Soyarslan C, Kim J, Kittiwirayanon B, Jeong J, Kim HJ, Huh YH, Kiener D, Bargmann S, and Gao H

Abstract

Materials displaying negative Poisson's ratio, referred to as auxeticity, have been found in nature and created in engineering through various structural mechanisms. However, uniting auxeticity with high strength and high stiffness has been challenging. Here, combining in situ nanomechanical testing with microstructure-based modeling, we show that the leading part of limpet teeth successfully achieves this combination of properties through a unique microstructure consisting of an amorphous hydrated silica matrix embedded with bundles of single-crystal iron oxide hydroxide nanorods arranged in a pseudo-cholesteric pattern. During deformation, this microstructure allows local coordinated displacement and rotation of the nanorods, enabling auxetic behavior while maintaining one of the highest strengths among natural materials. These findings lay a foundation for designing biomimetic auxetic materials with extreme strength and high stiffness.

Published
2022
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115. 100 years after Griffith: From brittle bulk fracture to failure in 2D materials.

Author

Kiener D and Han SM

Abstract

Brittle fracture and ductile failure are critical events for any structural or functional component, as it marks the end of lifetime and potential hazard to human life. As such, materials scientists continuously strive to better understand and subsequently avoid these events in modern materials. A century after the seminal initial contribution by Griffith, fracture mechanics has come a long way and is still experiencing vivid progress. Building on classical fracture testing standards, advanced in situ fracture experiments allow local quantitative probing of fracture processes on different length scales, while microscopic analysis grants access to chemical and structural information along fracture paths in previously unseen detail. This article will provide an overview of how these modern developments enhance our understanding of local fracture processes and highlight future trends toward designing strong yet ductile and damage-tolerant materials., (© The Author(s) 2022.)

Published
2022
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116. High-Temperature Nanoindentation of an Advanced Nano-Crystalline W/Cu Composite.

Author

Burtscher M, Zhao M, Kappacher J, Leitner A, Wurmshuber M, Pfeifenberger M, Maier-Kiener V, and Kiener D

Abstract

The applicability of nano-crystalline W/Cu composites is governed by their mechanical properties and microstructural stability at high temperatures. Therefore, mechanical and structural investigations of a high-pressure torsion deformed W/Cu nanocomposite were performed up to a temperature of 600 °C. Furthermore, the material was annealed at several temperatures for 1 h within a high-vacuum furnace to determine microstructural changes and surface effects. No significant increase of grain size, but distinct evaporation of the Cu phase accompanied by Cu pool and faceted Cu particle formation could be identified on the specimen's surface. Additionally, high-temperature nanoindentation and strain rate jump tests were performed to investigate the materials mechanical response at elevated temperatures. Hardness and Young's modulus decrease were noteworthy due to temperature-induced effects and slight grain growth. The strain rate sensitivity in dependent of the temperature remained constant for the investigated W/Cu composite material. Also, the activation volume of the nano-crystalline composite increased with temperature and behaved similar to coarse-grained W. The current study extends the understanding of the high-temperature behavior of nano-crystalline W/Cu composites within vacuum environments such as future fusion reactors.

Published
2021
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117. A Perspective to Control Laser-Induced Periodic Surface Structure Formation at Glancing-Incident Femtosecond Laser-Processed Surfaces.

Author

Jelinek A, Pfeifenberger MJ, Pippan R, and Kiener D

Abstract

The favorable combination of high material removal rate and low influence on the material beneath the ultra-short pulsed laser-processed surface are of particular advantage for sample preparation. This is especially true at the micrometer scale or for the pre-preparation for a subsequent focused ion beam milling process. Specific surface features, the laser-induced periodic surface structures, are generated on femtosecond laser-irradiated surfaces in most cases, which pose an issue for surface-sensitive mechanical testing or microstructural investigations. This work strives for an approach to enhance the surface quality of glancing-incident laser-processed surfaces on the model material copper with two distinctly different grain sizes. A new generalized perspective is presented, in which optimized parameter selection serves to counteract the formation of the laser-induced periodic surface structures, enabling, for example, grain orientation mapping directly on femtosecond laser processed surfaces., Supplementary Information: The online version contains supplementary material available at 10.1007/s11837-021-04963-w., Competing Interests: Conflict of interestThe authors declare that they have no conflict of interest., (© The Author(s) 2021.)

Published
2021
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118. Addressing H-Material Interaction in Fast Diffusion Materials-A Feasibility Study on a Complex Phase Steel.

Author

Massone A, Manhard A, Drexler A, Posch C, Ecker W, Maier-Kiener V, and Kiener D

Abstract

Hydrogen embrittlement (HE) is one of the main limitations in the use of advanced high-strength steels in the automotive industry. To have a better understanding of the interaction between hydrogen (H) and a complex phase steel, an in-situ method with plasma charging was applied in order to provide continuous H supply during mechanical testing in order to avoid H outgassing. For such fast-H diffusion materials, only direct observation during in-situ charging allows for addressing H effects on materials. Different plasma charging conditions were analysed, yet there was not a pronounced effect on the mechanical properties. The H concentration was calculated while using a simple analytical model as well as a simulation approach, resulting in consistent low H values, below the critical concentration to produce embrittlement. However, the dimple size decreased in the presence of H and, with increasing charging time, the crack propagation rate increased. The rate dependence of flow properties of the material was also investigated, proving that the material has no strain rate sensitivity, which confirmed that the crack propagation rate increased due to H effects. Even though the H concentration was low in the experiments that are presented here, different technological alternatives can be implemented in order to increase the maximum solute concentration.

Published
2020
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119. In-situ observation of the initiation of plasticity by nucleation of prismatic dislocation loops.

Author

Lee S, Vaid A, Im J, Kim B, Prakash A, Guénolé J, Kiener D, Bitzek E, and Oh SH

Abstract

The elastic-to-plastic transition during the deformation of a dislocation-free nanoscale volume is accompanied by displacement bursts associated with dislocation nucleation. The dislocations that nucleate during the so-called "pop-in" burst take the form of prismatic dislocation loops (PDLs) and exhibit characteristic burst-like emission and plastic recovery. Here, we report the in-situ transmission electron microscopy (TEM) observation of the initial plasticity ensued by burst-like emission of PDLs on nanoindentation of dislocation-free Au nanowires. The in-situ TEM nanoindentation showed that the nucleation and subsequent cross slip of shear loop(s) are the rate-limiting steps. As the indentation size increases, the cross slip of shear loop becomes favored, resulting in a transition from PDLs to open half-loops to helical dislocations. In the present case of nanoindentation of dislocation-free volumes, the PDLs glide out of the indentation stress field while spreading the plastic zone, as opposed to the underlying assumption of the Nix-Gao model.

Published
2020
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120. Bioinspired nacre-like alumina with a bulk-metallic glass-forming alloy as a compliant phase.

Author

Wat A, Lee JI, Ryu CW, Gludovatz B, Kim J, Tomsia AP, Ishikawa T, Schmitz J, Meyer A, Alfreider M, Kiener D, Park ES, and Ritchie RO

Abstract

Bioinspired ceramics with micron-scale ceramic "bricks" bonded by a metallic "mortar" are projected to result in higher strength and toughness ceramics, but their processing is challenging as metals do not typically wet ceramics. To resolve this issue, we made alumina structures using rapid pressureless infiltration of a zirconium-based bulk-metallic glass mortar that reactively wets the surface of freeze-cast alumina preforms. The mechanical properties of the resulting Al 2 O 3 with a glass-forming compliant-phase change with infiltration temperature and ceramic content, leading to a trade-off between flexural strength (varying from 89 to 800 MPa) and fracture toughness (varying from 4 to more than 9 MPa·m ½ ). The high toughness levels are attributed to brick pull-out and crack deflection along the ceramic/metal interfaces. Since these mechanisms are enabled by interfacial failure rather than failure within the metallic mortar, the potential for optimizing these bioinspired materials for damage tolerance has still not been fully realized.

Published
2019
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121. High Temperature Flow Behavior of Ultra-Strong Nanoporous Au assessed by Spherical Nanoindentation.

Author

Leitner A, Maier-Kiener V, and Kiener D

Abstract

Nanoporous metals have attracted attention in various research fields in the past years since their unique microstructures make them favorable for catalytic, sensory or microelectronic applications. Moreover, the refinement of the ligaments down to the nanoscale leads to an exceptionally high strength. To guarantee a smooth implementation of nanoporous metals into modern devices their thermo-mechanical behavior must be properly understood. Within this study the mechanical flow properties of nanoporous Au were investigated at elevated temperatures up to 300 °C. In contrast to the conventional synthesis by dealloying of AuAg precursors, the present foam was fabricated via severe plastic deformation of an AuFe nanocomposite and subsequent selective etching of iron, resulting in Au ligaments consisting of nanocrystalline grains, while remaining Fe impurities excessively stabilize the microstructure. A recently developed spherical nanoindentation protocol was used to extract the stress-strain curves of nanoporous Au. A tremendous increase of yield strength due to ligament and grain refinement was observed, which is largely maintained at high temperatures. Reviewing literature will evidence that the combined nanocrystalline and nanoporous structure leads to remarkable mechanical properties. Furthermore, comparison to a previous Berkovich nanoindentation study outlines the conformity of different indentation techniques.

Published
2018
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122. [Feline leukemia virus infection: importance and current situation in Switzerland].

Author

Hofmann-Lehmann R, Gönczi E, Riond B, Meli M, Willi B, Howard J, Schaarschmidt-Kiener D, Regli W, Gilli U, and Boretti F

Subjects
Animals, Cats, Leukemia, Feline virology, Retroviridae Infections epidemiology, Retroviridae Infections virology, Switzerland epidemiology, Tumor Virus Infections epidemiology, Tumor Virus Infections virology, Leukemia Virus, Feline isolation & purification, Leukemia, Feline epidemiology, Retroviridae Infections veterinary, Tumor Virus Infections veterinary
Abstract

Introduction: Feline leukemia virus (FeLV) leads to fatal disease in cats with progressive infection. The aim of this study was to determine the importance of FeLV infection in Switzerland and make a comparison with previous studies. Of 881 blood samples taken from cats living in Switzerland (minimum of 20 samples per Canton), 47 samples were provirus-positive (5.3%; 95% confidence interval (CI) 3.9-7.0%) and 18 samples were antigen-positive (2%; 95% CI 1.2-3.2%). Together with data previously collected in similar studies, these findings demonstrated a decrease in prevalence between 1997 and 2003 followed by a relative constant low prevalence thereafter. Young cats (=2 years) were more frequently infected than older cats, but FeLV-positive cats were up to 15 (antigen-positive) and 19 (provirus-positive) years old. Sexually intact cats were more frequently viremic than neutered cats; purebred cats were somewhat less frequently FeLV-positive than non-purebred cats. In a second study, in which 300 saliva samples were analyzed, samples from 5 cats were FeLV-RNA positive (1.7%; 95% CI, 0.5-3.8%), although one young feral cat had been falsely assumed to be FeLV-negative based on a point-of-care test. Of the 300 cats, only 50% were FeLV tested or vaccinated, although 90% of the cats were at risk of exposure to FeLV. Testing and vaccination of all cats with exposure risk may help further decrease the prevalence of FeLV infection. Moreover, characteristics of FeLV tests should be considered, such as the risk of false negative results in the early phase of infection when performing antigen testing.

Published
2018
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123. Substrate-Influenced Thermo-Mechanical Fatigue of Copper Metallizations: Limits of Stoney's Equation.

Author

Bigl S, Wurster S, Cordill MJ, and Kiener D

Abstract

Rapid progress in the reduction of substrate thickness for silicon-based microelectronics leads to a significant reduction of the device bending stiffness and the need to address its implication for the thermo-mechanical fatigue behavior of metallization layers. Results on 5 µm thick Cu films reveal a strong substrate thickness-dependent microstructural evolution. Substrates with h s = 323 and 220 µm showed that the Cu microstructure exhibits accelerated grain growth and surface roughening. Moreover, curvature-strain data indicates that Stoney's simplified curvature-stress relation is not valid for thin substrates with regard to the expected strains, but can be addressed using more sophisticated plate bending theories., Competing Interests: The authors declare no conflict of interest.

Published
2017
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124. The effect of size on the strength of FCC metals at elevated temperatures: annealed copper.

Author

Wheeler JM, Kirchlechner C, Micha JS, Michler J, and Kiener D

Abstract

As the length scale of sample dimensions is reduced to the micron and sub-micron scales, the strength of various materials has been observed to increase with decreasing size, a fact commonly referred to as the 'sample size effect'. In this work, the influence of temperature on the sample size effect in copper is investigated using in situ microcompression testing at 25, 200 and 400 °C in the SEM on vacuum-annealed copper structures, and the resulting deformed structures were analysed using X-ray μLaue diffraction and scanning electron microscopy. For pillars with sizes between 0.4 and 4 μm, the size effect was measured to be constant with temperature, within the measurement precision, up to half of the melting point of copper. It is expected that the size effect will remain constant with temperature until diffusion-controlled dislocation motion becomes significant at higher temperatures and/or lower strain rates. Furthermore, the annealing treatment of the copper micropillars produced structures which yielded at stresses three times greater than their un-annealed, FIB-machined counterparts.

Published
2016
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125. Synthesis and Mechanical Characterisation of an Ultra-Fine Grained Ti-Mg Composite.

Author

Alfreider M, Jeong J, Esterl R, Oh SH, and Kiener D

Abstract

The importance of lightweight materials such as titanium and magnesium in various technical applications, for example aerospace, medical implants and lightweight construction is well appreciated. The present study is an attempt to combine and improve the mechanical properties of these two materials by forming an ultra-fine grained composite. The material, with a composition of 75 vol% (88.4 wt%) Ti and 25 vol% (11.4 wt%) Mg , was synthesized by powder compression and subsequently deformed by high-pressure torsion. Using focused ion beam machining, miniaturised compression samples were prepared and tested in-situ in a scanning electron microscope to gain insights into local deformation behaviour and mechanical properties of the nanocomposite. Results show outstanding yield strength of around 1250 MPa, which is roughly 200 to 500 MPa higher than literature reports of similar materials. The failure mode of the samples is accounted for by cracking along the phase boundaries.

Published
2016
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126. Thermally Activated Deformation Behavior of ufg-Au: Environmental Issues During Long-Term and High-Temperature Nanoindentation Testing.

Author

Maier V, Leitner A, Pippan R, and Kiener D

Abstract

For testing time-dependent material properties by nanoindentation, in particular for long-term creep or relaxation experiments, thermal drift influences on the displacement signal are of prime concern. To address this at room and elevated temperatures, we tested fused quartz at various contact depths at room temperature and ultra-fine grained (ufg) Au at various temperatures. We found that the raw data for fused quartz are strongly affected by thermal drift, but corrected by use of dynamic stiffness measurements all the datasets collapse. The situation for the ufg Au shows again that the data are only useful with drift correction, but with this applied it turns out that there is a significant change of elastic and plastic properties when exceeding 200°C, which is also reflected by an increasing strain rate sensitivity.

Published
2015
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127. Fabrication and thermo-mechanical behavior of ultra-fine porous copper.

Author

Kreuzeder M, Abad MD, Primorac MM, Hosemann P, Maier V, and Kiener D

Abstract

Porous materials with ligament sizes in the submicrometer to nanometer regime have a high potential for future applications such as catalysts, actuators, or radiation tolerant materials, which require properties like high strength-to-weight ratio, high surface-to-volume ratio, or large interface density as for radiation tolerance. The objective of this work was to manufacture ultra-fine porous copper, to determine the thermo-mechanical properties, and to elucidate the deformation behavior at room as well as elevated temperatures via nanoindentation. The experimental approach for manufacturing the foam structures used high pressure torsion, subsequent heat treatments, and selective dissolution. Nanoindentation at different temperatures was successfully conducted on the ultra-fine porous copper, showing a room temperature hardness of 220 MPa. During high temperature experiments, oxidation of the copper occurred due to the high surface area. A model, taking into account the mechanical properties of the copper oxides formed during the test, to describe the measured mechanical properties in dependence on the proceeding oxidation was developed. The strain rate sensitivity of the copper foam at room temperature was ∼0.03 and strongly correlated with the strain rate sensitivity of ultra-fine grained bulk copper. Although oxidation occurred near the surface, the rate-controlling process was still the deformation of the underlying copper. An increase in the strain rate sensitivity was observed, comparably to that of ultra-fine-grained copper, which can be linked to thermally activated processes at grain boundaries. Important insights into the effects of oxidation on the deformation behavior were obtained by assessing the activation volume. Oxidation of the ultra-fine porous copper foam, thereby hindering dislocations to exit to the surface, resulted in a pronounced reduction of the apparent activation volume from ~800 to ~50  b 3 , as also typical for ultra-fine grained materials.

Published
2015
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128. Analysis of the population structure of Anaplasma phagocytophilum using multilocus sequence typing.

Author

Huhn C, Winter C, Wolfsperger T, Wüppenhorst N, Strašek Smrdel K, Skuballa J, Pfäffle M, Petney T, Silaghi C, Dyachenko V, Pantchev N, Straubinger RK, Schaarschmidt-Kiener D, Ganter M, Aardema ML, and von Loewenich FD

Subjects
Anaplasmosis microbiology, Animals, Animals, Domestic microbiology, Ehrlichiosis microbiology, Humans, Multilocus Sequence Typing, Anaplasma phagocytophilum genetics, RNA, Ribosomal, 16S genetics
Abstract

Anaplasma phagocytophilum is a Gram-negative obligate intracellular bacterium that replicates in neutrophils. It is transmitted via tick-bite and causes febrile disease in humans and animals. Human granulocytic anaplasmosis is regarded as an emerging infectious disease in North America, Europe and Asia. However, although increasingly detected, it is still rare in Europe. Clinically apparent A. phagocytophilum infections in animals are mainly found in horses, dogs, cats, sheep and cattle. Evidence from cross-infection experiments that A. phagocytophilum isolates of distinct host origin are not uniformly infectious for heterologous hosts has led to several approaches of molecular strain characterization. Unfortunately, the results of these studies are not always easily comparable, because different gene regions and fragment lengths were investigated. Multilocus sequence typing is a widely accepted method for molecular characterization of bacteria. We here provide for the first time a universal typing method that is easily transferable between different laboratories. We validated our approach on an unprecedented large data set of almost 400 A. phagocytophilum strains from humans and animals mostly from Europe. The typability was 74% (284/383). One major clonal complex containing 177 strains was detected. However, 54% (49/90) of the sequence types were not part of a clonal complex indicating that the population structure of A. phagocytophilum is probably semiclonal. All strains from humans, dogs and horses from Europe belonged to the same clonal complex. As canine and equine granulocytic anaplasmosis occurs frequently in Europe, human granulocytic anaplasmosis is likely to be underdiagnosed in Europe. Further, wild boars and hedgehogs may serve as reservoir hosts of the disease in humans and domestic animals in Europe, because their strains belonged to the same clonal complex. In contrast, as they were only distantly related, roe deer, voles and shrews are unlikely to harbor A. phagocytophilum strains infectious for humans, domestic or farm animals.

Published
2014
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129. Reversible cyclic deformation mechanism of gold nanowires by twinning-detwinning transition evidenced from in situ TEM.

Author

Lee S, Im J, Yoo Y, Bitzek E, Kiener D, Richter G, Kim B, and Oh SH

Abstract

Mechanical response of metal nanowires has recently attracted a lot of interest due to their ultra-high strengths and unique deformation behaviours. Atomistic simulations have predicted that face-centered cubic metal nanowires deform in different modes depending on the orientation between wire axis and loading direction. Here we report, by combination of in situ transmission electron microscopy and molecular dynamic simulation, the conditions under which particular deformation mechanisms take place during the uniaxial loading of [110]-oriented Au nanowires. Furthermore, by performing cyclic uniaxial loading, we show reversible plastic deformation by twinning and consecutive detwinning in tension and compression, respectively. Molecular dynamics simulations rationalize the observed behaviours in terms of the orientation-dependent resolved shear stress on the leading and trailing partial dislocations, their potential nucleation sites and energy barriers. This reversible twinning-detwinning process accommodates large strains that can be beneficially utilized in applications requiring high ductility in addition to ultra-high strength.

Published
2014
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130. Strength, Hardening, and Failure Observed by In Situ TEM Tensile Testing.

Author

Kiener D, Kaufmann P, and Minor AM

Abstract

We present in situ transmission electron microscope tensile tests on focused ion beam fabricated single and multiple slip oriented Cu tensile samples with thicknesses in the range of 100-200 nm. Both crystal orientations fail by localized shear. While failure occurs after a few percent plastic strain and limited hardening in the single slip case, the multiple slip samples exhibit extended homogenous deformation and necking due to the activation of multiple dislocation sources in conjunction with significant hardening. The hardening behavior at 1% plastic strain is even more pronounced compared to compression samples of the same orientation due to the absence of sample taper and the interface to the compression platen. Moreover, we show for the first time that the strain rate sensitivity of such FIB prepared samples is an order of magnitude higher than that of bulk Cu.

Published
2012
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131. Distinct host species correlate with Anaplasma phagocytophilum ankA gene clusters.

Author

Scharf W, Schauer S, Freyburger F, Petrovec M, Schaarschmidt-Kiener D, Liebisch G, Runge M, Ganter M, Kehl A, Dumler JS, Garcia-Perez AL, Jensen J, Fingerle V, Meli ML, Ensser A, Stuen S, and von Loewenich FD

Subjects
Anaplasma phagocytophilum genetics, Animals, Cattle, Cluster Analysis, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA, Ribosomal chemistry, DNA, Ribosomal genetics, Humans, Molecular Sequence Data, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anaplasma phagocytophilum classification, Anaplasma phagocytophilum isolation & purification, Bacterial Proteins genetics, Ehrlichiosis microbiology, Ehrlichiosis veterinary, Polymorphism, Genetic
Abstract

Anaplasma phagocytophilum is a gram-negative, tick-transmitted, obligate intracellular bacterium that elicits acute febrile diseases in humans and domestic animals. In contrast to the United States, human granulocytic anaplasmosis seems to be a rare disease in Europe despite the initial recognition of A. phagocytophilum as the causative agent of tick-borne fever in European sheep and cattle. Considerable strain variation has been suggested to occur within this species, because isolates from humans and animals differed in their pathogenicity for heterologous hosts. In order to explain host preference and epidemiological diversity, molecular characterization of A. phagocytophilum strains has been undertaken. Most often the 16S rRNA gene was used, but it might be not informative enough to delineate distinct genotypes of A. phagocytophilum. Previously, we have shown that A. phagocytophilum strains infecting Ixodes ricinus ticks are highly diverse in their ankA genes. Therefore, we sequenced the 16S rRNA and ankA genes of 194 A. phagocytophilum strains from humans and several animal species. Whereas the phylogenetic analysis using 16S rRNA gene sequences was not meaningful, we showed that distinct host species correlate with A. phagocytophilum ankA gene clusters.

Published
2011
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132. Perylene-labeled silica nanoparticles: synthesis and characterization of three novel silica nanoparticle species for live-cell imaging.

Author

Blechinger J, Herrmann R, Kiener D, García-García FJ, Scheu C, Reller A, and Bräuchle C

Subjects
Fluorescence Polarization methods, HeLa Cells, Humans, Microscopy, Confocal methods, Microscopy, Electron, Transmission, Nanoparticles ultrastructure, Spectrometry, Fluorescence methods, Nanoparticles chemistry, Perylene chemistry, Silicon Dioxide chemistry
Abstract

The increasing exposure of humans to nanoscaled particles requires well-defined systems that enable the investigation of the toxicity of nanoparticles on the cellular level. To facilitate this, surface-labeled silica nanoparticles, nanoparticles with a labeled core and a silica shell, and a labeled nanoparticle network-all designed for live-cell imaging-are synthesized. The nanoparticles are functionalized with perylene derivatives. For this purpose, two different perylene species containing one or two reactive silica functionalities are prepared. The nanoparticles are studied by transmission electron microscopy, widefield and confocal fluorescence microscopy, as well as by fluorescence spectroscopy in combination with fluorescence anisotropy, in order to characterize the size and morphology of the nanoparticles and to prove the success and homogeneity of the labeling. Using spinning-disc confocal measurements, silica nanoparticles are demonstrated to be taken up by HeLa cells, and they are clearly detectable inside the cytoplasm of the cells.

Published
2010
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133. [Anaplasma phagocytophilum infection in a cat in Switzerland].

Author

Schaarschmidt-Kiener D, Graf F, von Loewenich FD, and Müller W

Subjects
Animals, Cats, DNA, Bacterial analysis, Ehrlichiosis diagnosis, Ehrlichiosis drug therapy, Male, Polymerase Chain Reaction veterinary, Switzerland, Treatment Outcome, Anaplasma phagocytophilum isolation & purification, Anti-Bacterial Agents therapeutic use, Cat Diseases diagnosis, Cat Diseases drug therapy, Doxycycline therapeutic use, Ehrlichiosis veterinary
Abstract

The following case report describes the diagnosis and therapy of a cat with an Anaplasma phagocytophilum infection. The cat from the canton of St. Gallen was presented because of lethargy and lack of appetite. The clinical symptoms established were fever and minor exsiccosis. The diagnosis of granulocytic anaplasmosis was established through microscopic evidence of inclusion bodies in neutrophil granulocytes, the detection of pathogen DNA in the blood by PCR and positive IgM and IgG antibody titers by serological testing. Following this diagnosis the cat was treated for 20 days with doxycycline. As the body temperature normalised, the activity of the cat improved while normalisation of food intake was delayed. After therapy Anaplasma phagocytophilum DNA could not be detected by PCR and a complete remission of abnormal serum chemistry and hematological parameters could be shown.

Published
2009
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134. Synthesis and biological evaluation of a bioresponsive and endosomolytic siRNA-polymer conjugate.

Author

Meyer M, Dohmen C, Philipp A, Kiener D, Maiwald G, Scheu C, Ogris M, and Wagner E

Subjects
Animals, Cell Line, Tumor, Cell Survival drug effects, Drug Stability, Electrophoresis, Agar Gel, Glutathione chemistry, Hydrogen-Ion Concentration, Luciferases genetics, Luciferases metabolism, Melitten chemistry, Mice, Polyethylene Glycols chemistry, Polylysine chemistry, Polymers chemistry, RNA, Small Interfering chemistry, Polymers chemical synthesis, Polymers pharmacology, RNA, Small Interfering chemical synthesis, RNA, Small Interfering pharmacology
Abstract

Extracellular stability of electrostatically formed siRNA polyplexes is a significant concern in the delivery process. To overcome the risk of polyplex dissociation in the extracellular environment, siRNA was covalently incorporated into a pH- and redox-responsive polymer conjugate. The novel siRNA conjugate consists of polylysine (PLL) as RNA binding and protecting polycation, polyethylene glycol (PEG) as solubilizing and shielding polymer, the lytic peptide melittin masked by dimethylmaleic anhydride (DMMAn) removable at endosomal pH, and the siRNA attached at the 5'-end of the sense strand via a bioreducible disulfide bond. The purified siRNA conjugate was stable in the presence of the polyanion heparin at conditions where the analogous electrostatic siRNA polyplexes disassemble. Only the combination of heparin plus a reducing agent such as glutathione triggered the release of siRNA from the conjugate. High in vitro biocompatibility (absence of cytotoxicity or hemolytic activity at neutral pH) and efficient and sequence-specific gene silencing was found at > or =25 nM siRNA, comparable to the corresponding electrostatic polyplexes. In vivo toxicity studies of this formulation demonstrated that conjugates remain to be optimized for therapeutic application.

Published
2009
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135. In situ observation of dislocation nucleation and escape in a submicrometre aluminium single crystal.

Author

Oh SH, Legros M, Kiener D, and Dehm G

Abstract

'Smaller is stronger' does not hold true only for nanocrystalline materials but also for single crystals. It is argued that this effect is caused by geometrical constraints on the nucleation and motion of dislocations in submicrometre-sized crystals. Here, we report the first in situ transmission electron microscopy tensile tests of a submicrometre aluminium single crystal that are capable of providing direct insight into source-controlled dislocation plasticity in a submicrometre crystal. Single-ended sources emit dislocations that escape the crystal before being able to multiply. As dislocation nucleation and loss rates are counterbalanced at about 0.2 events per second, the dislocation density remains statistically constant throughout the deformation at strain rates of about 10(-4) s(-1). However, a sudden increase in strain rate to 10(-3) s(-1) causes a noticeable surge in dislocation density as the nucleation rate outweighs the loss rate. This observation indicates that the deformation of submicrometre crystals is strain-rate sensitive.

Published
2009
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136. Disorders of the salivary glands.

Author

Kiener DJ

Subjects
Aged, Bacterial Infections diagnosis, Humans, Lymphatic Diseases diagnosis, Male, Mumps diagnosis, Parotid Gland anatomy & histology, Parotid Neoplasms diagnosis, Salivary Duct Calculi diagnosis, Sialadenitis diagnosis, Sialography, Submandibular Gland anatomy & histology, Tomography, X-Ray Computed, Salivary Gland Diseases diagnosis, Salivary Gland Neoplasms diagnosis
Published
1982

137. Effects of repeated stripping on vocal fold mucosa in cats.

Author

Leonard RJ, Kiener D, Charpied G, and Kelly A

Subjects
Animals, Cats, Humans, Nerve Endings pathology, Postoperative Complications etiology, Reoperation, Time Factors, Vocal Cords innervation, Vocal Cords pathology, Voice Quality, Laryngeal Mucosa pathology, Larynx pathology, Vocal Cords surgery
Abstract

Repeated stripping of the vocal folds in patients with recurrent vocal nodules may produce permanent, negative effects on voice quality. Hoarseness can be present with no evidence of structural or functional disease on indirect laryngoscopy. A common assumption is that scar tissue has formed, though the relationship between scarring and voice quality is not clear. In the study reported here, cats were subjected to four strippings of the left vocal fold at 6- to 8-week intervals. Tissues obtained were examined for changes in the composition of the mucosa and its nervous network. Alterations observed over the four strippings included 1) an increasing component of fibrous tissue and 2) apparent changes in both the number and structure of nervous elements. Implications of the findings for voice production, clinical management, and further research are discussed.

Published
1985

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