The brittle-to-ductile transition in cold-rolled tungsten sheets: the rate-limiting mechanism of plasticity controlling the BDT in ultrafine-grained tungsten

Conventionally produced tungsten (W) sheets are brittle at room temperature. In contrast to that, severe deformation by cold rolling transforms W into a material exhibiting room-temperature ductility with a brittle-to-ductile transition (BDT) temperature far below room temperature. For such ultrafine-grained (UFG) and dislocation-rich materials, the mechanism controlling the BDT is still the subject of ongoing debates. In order to identify the mechanism controlling the BDT in room-temperature ductile W sheets with UFG microstructure, we conducted campaigns of fracture toughness tests accompanied by a thermodynamic analysis deducing Arrhenius BDT activation energies. Here, we show that plastic deformation induced by rolling reduces the BDT temperature and also the BDT activation energy. A comparison of BDT activation energies with the trend of Gibbs energy of kink-pair formation revealed a strong correlation between both quantities. This demonstrates that out of the three basic processes, nucleation, glide, and annihilation, crack tip plasticity in UFG W is still controlled by the glide of dislocations. The glide is dictated by the mobility of the screw segments and therefore by the underlying process of kink-pair formation. Reflecting this result, a change of the rate-limiting mechanism for plasticity of UFG W seems unlikely, even at deformation temperatures well below room temperature. As a result, kink-pair formation controls the BDT in W over a wide range of microstructural length scales, from single crystals and coarse-grained specimens down to UFG microstructures

Direct Laser Interference Patterning: Tailoring of Contact Area for Frictional and Antibacterial Properties

Surface functionalization by topographic micro- and nano-structures in order to achieve unique properties, like super-hydrophobicity or ultrahigh light absorption, is a common strategy in nature. In this paper, direct laser interference patterning (DLIP) is presented as a promising tool allowing for the generation of such surface patterns on technical surfaces in order to mimic these biological surfaces and effects. Friction optimization and antibacterial effects by DLIP are exemplarily described. Topographic surface patterns on the micro- and nano-scale demonstrated a significant reduction in the coefficient of friction and bacterial adhesion. It was shown that in both cases, the control of the contact area between surfaces or between surface and bacteria is of utmost importance

Klinische und radiologische Ergebnisse nach modifizierter Drittelrohr-Hakenplattenosteosynthese bei Olecranonfrakturen

Meeting Abstract : Deutscher Kongress für Orthopädie und Unfallchirurgie ; 73. Jahrestagung der Deutschen Gesellschaft für Unfallchirurgie ; 95. Tagung der Deutschen Gesellschaft für Orthopädie und Orthopädische Chirurgie ; 50. Tagung des Berufsverbandes der Fachärzte für Orthopädie und Unfallchirurgie ; 21. - 24.10.2009, Berlin Fragestellung: Ziel war die Evaluierung der funktionellen und radiologischen Ergebnisse nach osteosynthestischer Versorgung von Olecranonfrakturen mit einer zur Hakenplatte modifizierten Drittelrohrplatte. Methodik: In einem Zeitraum von 12 Monaten wurden 29 Patienten mit Olecranonfrakturen prospektiv erfasst und eine Osteosynthese mit einer zur Hakenplatte modifizierten Kleinfragment-Drittelrohrplatte durchgeführt. Eine additive Verschraubung von zusätzlichen Fragmenten erfolgte bei 6 Patienten (20%). Das mittlere Patientenalter zum Unfallzeitpunkt betrug 50 Jahre (Min 29/ Max 83). Unter Verwendung der Frakturklassifikation nach Schatzker stellte sich in 8 Fällen (28%) eine Querfraktur vom Typ A, in 6 Fällen (20%) eine Querfraktur mit Impaktion vom Typ B und in 15 Fällen (52%) eine Mehrfragmentfraktur vom Typ D dar. Bei 4 Patienten (14%) lag eine offene Fraktursituation vor. Nach im Mittel 7,2 Monaten (Min 6/ Max 8) wurde das funktionelle Outcome anhand des Mayo Elbow Performence Scores (MEPS), der visuellen Analogskala (VAS) und des Disabilities of the Arm, Shoulder and Hand Scores (DASH) bewertet sowie die radiologischen Befunde erhoben. Ergebnisse und Schlussfolgerungen: Das Ziel einer primär übungsstabilen Osteosynthese konnte bei allen Patienten erreicht werden. Unter Verwendung des MEPS wurden annähernd ausschließlich sehr gute (12 Fälle/41%) und gute (16 Fälle/55%) Ergebnisse erzielt. Lediglich bei einem Patienten ergab sich ein nur befriedigendes Ergebnis. Der mittlere Punktwert für den MEPS betrug 91,4 (Min 65/Max 100). In der VAS konnte ein Mittelwert von 8,2 Punkten (Min 7/Max 10) erzielt werden (0=keine Zufriedenheit, 10=volle Zufriedenheit). Der mittlere DASH-Wert betrug 16,2 Punkte (Min 0/Max 39). Der mittlere Bewegungsumfang betrug für Extension/Flexion bei einem durchschnittlichen Streckdefizit von 8° (Min 0°/Max 25°) und einer Beugung von 135° (Min 105°/Max 155°) 125° (Min 90°/Max 155°). Die Unterarmumwendbewegungen waren mit 175° (Min 165°/Max 180°) kaum eingeschränkt. Bei keinem Patienten gab es postoperative Komplikationen. Eine zur Hakenplatte modifizierte Drittelrohrplatte stellt im Gegensatz zu präformierten, winkelstabilen Implantaten eine kostengünstige Alternative zur Osteosynthese bei Olecranonfrakturen dar. Auch bei komplexen mehrfragmentären Frakturtypen und osteoporotischer Knochenqualität konnte so im nachuntersuchten Kollektiv eine sichere Frakturretention erzielt werden. Hinsichtlich des funktionellen Ergebnisses profitieren die Patienten von einer dadurch unmittelbar postoperativ möglichen, physiotherapeutischen Nachbehandlung. Das für die Hakenplatte benötigte Osteosynthesematerial (Kleinfragment-Drittelrohrplatte) ist nahezu überall verfügbar und lässt sich in kurzer Zeit der individuellen Anatomie und Frakturmorphologie anpassen. Eine Drahtmigration, wie bei der weit verbreiteten Zuggurtungsosteosynthese häufig beobachtet, ist ausgeschlossen

In-situ microscopy and 2D fluorescence spectroscopy as online methods for monitoring CHO cells during cultivation

Typical methods for monitoring cultivation processes are offline analyses like cell counting, measurement of various substrates and products (e. g. glucose or lactate) as well as the online monitoring of several physical process parameters (temperature, pH-value or the concentration of dissolved oxygen). To improve cell cultivations detailed information about important analytes should be available online. Therefore new monitoring methods need to be established, preferably as in-situ methods to minimize the risk of contamination. Two different in-situ online-methods were used to monitor cultivations: In-situ microscopy and 2D fluorescence spectroscopy. Therefore CHO-K1 cells (provided by University of Bielefeld) were cultivated in a complex culture medium (TC 42, TeutoCell, Bielefeld, Germany) using a 2.5 L stainless steel reactor with a work volume of 2 L. A total of three cultivation runs were conducted

Reliability and validity of needle biopsy evaluation of breast-abnormalities using the B-categorization – design and objectives of the Diagnosis Optimisation Study (DIOS)

<p>Abstract</p> <p>Background</p> <p>The planned nationwide implementation of mammography screening 2007 in Germany will increase the occurrence of mammographically detected breast abnormalities. These abnormalities are normally evaluated by minimal invasive core biopsy. To minimize false positive and false negative histological findings, quality assurance of the pathological evaluation of the biopsies is essential. Various guidelines for quality assurance in breast cancer diagnosis recommend applying the B-classification for histopathological categorization. However, to date there are only few studies that reported results about reliability and validity of B-classification. Therefore, objectives of our study are to determine the inter- and intraobserver variability (reliability study) and construct and predictive validity (validity study) of core biopsy evaluation of breast abnormalities. This paper describes the design and objectives of the DIOS Study.</p> <p>Methods/Design</p> <p>All consecutive asymptomatic and symptomatic women with breast imaging abnormalities who are referred to the University Hospital of Halle for core breast biopsy over a period of 24 months are eligible. According to the sample size calculation we need 800 women for the study. All patients in the study population underwent clinical and radiological examination. Core biopsy is performed by stereotactic-, ultrasound- or magnetic resonance (MR) guided automated gun method or vacuum assisted method. The histopathologic agreement (intra- and interobserver) of pathologists and the histopathologic validity will be evaluated. Two reference standards are implemented, a reference pathologist and in case of suspicious or malignant findings the histopathologic result of excision biopsy. Furthermore, a self administrated questionnaire which contains questions about potential risk factors of breast cancer, is sent to the participants approximately two weeks after core biopsy. This enables us to run a case-control-analysis (woman with breast cancer histological verified after excision are defined as cases, woman without malignant breast lesions are defined as controls) to investigate the predictive values of various risk factors on breast cancer risk.</p> <p>Conclusion</p> <p>The analysis of reliability and validity of the histopathological evaluation of core biopsy specimens of breast abnormalities is intended to provide important information needed for a high quality in breast cancer diagnostic and for planning of treatment strategies.</p

Direct Laser Interference Patterning: Tailoring of Contact Area for Frictional and Antibacterial Properties

Surface functionalization by topographic micro- and nano-structures in order to achieve unique properties, like super-hydrophobicity or ultrahigh light absorption, is a common strategy in nature. In this paper, direct laser interference patterning (DLIP) is presented as a promising tool allowing for the generation of such surface patterns on technical surfaces in order to mimic these biological surfaces and effects. Friction optimization and antibacterial effects by DLIP are exemplarily described. Topographic surface patterns on the micro- and nano-scale demonstrated a significant reduction in the coefficient of friction and bacterial adhesion. It was shown that in both cases, the control of the contact area between surfaces or between surface and bacteria is of utmost importance

Comparison of K-doped and pure cold-rolled tungsten sheets: Tensile properties and brittle-to-ductile transition temperatures

For high-temperature environments, as in future fusion reactors, the use of tungsten materials has been sincerely discussed in the last decade. Although severe cold-rolling of tungsten leads to significant improvements in mechanical properties, the fine-grained microstructure of such tungsten material has to be stabilized. For that, the use of potassium-doping (K-doping) in tungsten sheets is investigated in our ongoing study. In this work, we compare mechanical properties of warm- and cold-rolled sheets of pure tungsten and K-doped tungsten (for five different degree of deformation respectively) by means of fracture toughness tests and tensile tests. Fracture toughness and brittle-to-ductile transition temperatures (TBDT) are assessed, showing a slightly lower transition temperature for the cold-rolled K-doped sheets (lower than −100 °C for the 50 µm thick foil). The better performance of the K-doped sheet is related to its finer grain size. The thickest K-doped sheet shows a much higher TBDT than its pure tungsten counterpart. This is presumably caused by the presence of several tens of micrometre thick bands, containing only low angle boundaries, in the microstructure of the K-doped sheet. Tensile tests reveal an outstanding yield strength of 2860 MPa and an ultimate tensile strength of 2970 MPa for the thinnest K-doped sheet with similar, but slightly lower values for the pure tungsten counterpart. Both thinnest sheets show a drastic increase in ultimate tensile strength in correlation to their mean grain size, much higher than expected by a Hall-Petch relation. This deviation has been observed for the microhardness as well and is assumed to be caused by an extraordinary increase in the density of dislocations. Our results indicate that no disadvantages in tensile strength and brittle-to-ductile transition are to be expected compared to pure tungsten, when K-doped tungsten is used to inhibit recrystallization in high-temperature environments