Wear Resistant Amorphous and Nanocomposite Coatings

Glass forming materials (critical cooling rate <10{sup 4}K.s{sup -1}) are promising for their high corrosion and wear resistance. During rapid cooling, the materials form an amorphous structure that transforms to nanocrystalline during a process of devitrification. High hardness (HV 1690) can be achieved through a controlled crystallization. Thermal spray process has been used to apply coatings, which preserves the amorphous/nanocomposite structure due to a high cooling rate of the feedstock particles during the impact on a substrate. Wear properties have been studied with respect to process conditions and feedstock material properties. Application specific properties such as sliding wear resistance have been correlated with laboratory tests based on instrumented indentation and scratch tests

Repeated slip along a major decoupling horizon between crustal-scale nappesof the Central Western Carpathians documented in the Ochtinà tectonicmélange

International audienceThe Ochtiná Unit is situated in the ENE-WSW-trending contact zone between two crustal-scale nappes, the upper Gemer Unit and the lower Vepor Unit, in the Central Western Carpathians, Slovakia. The Ochtiná Unit consists mainly of Carboniferous phyllitic schists and sandstones enclosing lenses of diverse lithological nature and contrasting metamorphic history. Peak PT conditions obtained by means of phase equilibrium modelling from lenses of amphibolite and chloritoid schist in this unit indicate 500-600 °C and 4-6.5 kbar and 500-520 °C and 9-11 kbar, respectively. These PT conditions contrast not only with the greenschist-facies metamorphism of dominant phyllite but also with each other documenting two distinct metamorphic field gradients related to Variscan and Alpine metamorphic events. Geochemical data reveal an affinity of the amphibolite lenses to similar Variscan rocks in the basement of the upper Gemer Unit and of the chloritoid schist to similar Alpine rocks in the cover of the lower Vepor Unit. Such heterogeneous lithological and metamorphic record is consistent with a block-in-matrix rock arrangement and the Ochtiná Unit is interpreted as deep seated tectonic mélange. The mélange evolved via repeated slip along the rheologically weak sediments of the Ochtiná Unit during the building and collapse of the Eo-Alpine orogenic wedge of the Central Western Carpathians. Deformation record indicates that the mélange separates two distinct structural domains marked by a decoupled behaviour, i.e. the orogenic suprastructure represented by the Gemer Unit and the infrastructure represented by the Vepor Unit. With this respect, the Ochtiná Unit represents an unusual example of a suprastructure-infrastructure transition zone with its position being controlled by the mechanical weakness of this sedimentary horizon and not by the temperature-dependent rheological transition

Several Distinct Polycomb Complexes Regulate and Co-Localize on the INK4a Tumor Suppressor Locus

Misexpression of Polycomb repressive complex 1 (PRC1) components in human cells profoundly influences the onset of cellular senescence by modulating transcription of the INK4a tumor suppressor gene. Using tandem affinity purification, we find that CBX7 and CBX8, two Polycomb (Pc) homologs that repress INK4a, both participate in PRC1-like complexes with at least two Posterior sex combs (Psc) proteins, MEL18 and BMI1. Each complex contains a single representative of the Pc and Psc families. In primary human fibroblasts, CBX7, CBX8, MEL18 and BMI1 are present at the INK4a locus and shRNA-mediated knockdown of any one of these components results in de-repression of INK4a and proliferative arrest. Sequential chromatin immunoprecipitation (ChIP) reveals that CBX7 and CBX8 bind simultaneously to the same region of chromatin and knockdown of one of the Pc or Psc proteins results in release of the other, suggesting that the binding of PRC1 complexes is interdependent. Our findings provide the first evidence that a single gene can be regulated by several distinct PRC1 complexes and raise important questions about their configuration and relative functions

Adenovirus-mediated TA-p73β gene transfer increases chemosensitivity of human malignant melanomas

Malignant melanoma is the most aggressive form of skin cancer and has proven to be highly resistant to conventional chemotherapy. Intriguingly, the p53 tumor suppressor, a main mediator of chemoresistance in other tumor types, is rarely mutated in melanoma. However, we have previously shown that anti-apoptotic isoforms of p73 (ΔTA-p73), another member of the p53 family, are overexpressed in metastatic melanomas. ΔTA-p73 can oppose the pro-apoptotic functions of p53 and full length p73, and thus it could contribute to melanoma chemoresistance. In this study, we use an efficient adenoviral-based gene transfer approach to introduce a transcriptionally active form of p73 (TA-p73β) in melanoma cells, with the objective of overcoming drug resistance. Interestingly, TA-p73β significantly sensitized 5 out of 7 aggressive melanoma cell lines to the standard therapeutic agents adriamycin and cisplatin. More importantly, TA-p73β displayed a synergistic effect in vivo allowing adriamycin or cisplatin to block melanoma cell growth in mouse xenograft models ( p < 0.05). In summary, our data show that Ad-mediated TA-p73β gene expression can markedly sensitize a subset of melanoma cell lines to adriamycin and cisplatin in vitro and in vivo , suggesting a new chemosensitization strategy for malignant melanomas.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/44369/1/10495_2006_Article_3407.pd

Mechanical property variations within thermal barrier coatings

The mechanical properties of nanostructured yttria stabilized zirconia (YSZ) coatings were investigated using an instrumented indentation technique. Coatings were produced using the Triple-Torch Plasma Reactor (TTPR) where three plasma jet plumes converge to form a single jet where powder is injected axially. Partially fused clusters of sub-micron particles are characteristic for the coating microstructure. Flattened particles, termed as splats that are typical for conventional YSZ coatings were not observed.\ud \ud The microstructure exhibits a low isotropy that is related to variations in mechanical properties that are measured in directions parallel (normal to the coating plane) and perpendicular to the spray direction (in the plane of the coating). The microstructure of the nanostructured coating, which is different from a conventional coating, has a significant effect on the anisotropy of the mechanical properties. The in-plane elastic modulus of the nanostructured coating is lower than the normal modulus, as opposed to a conventional YSZ coating where the ratio is inversed. Multiple indentations arranged in arrays were used to map the variation in mechanical properties. Indentation results obtained using spherical and Vickers indenters are compared

Rock slope monitoring data

Environmental and crack meter data to 27.1.202

landslide susceptibility of Czechia

results of susceptibility models that were calculated using logistic regressio

XFEM modeling of effective thermal properties and fracture of thermal barrier coatings

An in-house Extended Finite Element code is employed to simulate the effect of cracks within a TBC system with a\ud YSZ top coat and a mullite intermediate layer deposited onto a SiC substrate. Microstructural level analysis consists in decomposition of a micrograph into an image showing the crack structure and then image capturing the\ud distribution of pores and coating materials. This later image is used to generate the adaptive Finite Element (FE)\ud mesh while the first image defines a discontinuous enrichment of the FE approximation of the displacement field.\ud \ud This analysis process is versatile and takes into account the presence of the cracks within the coating so that the\ud fracture behavior can be estimated. Stress intensity factors of selected through-thickness cracks were calculated\ud from a domain form of the interaction integral. The concept of XFEM is also extended to thermal analysis. Again, the FE approximation is enriched in a way similar to the previous case; however the weak form is modified to enforce proper temperature changes across the crack width. The cracks are modeled as thermal insulating layers with resistance determined from the kinetic theory of gases. The effective thermal conductivity of the coating is, thereby, predicted

Microstructural observation of the sintering behavior of nanostructured yttria stabilized zirconia

Multilayer thermal barrier coatings are being investigated for high temperature applications by employing a strain\ud accommodating interlayer. Plasma sprayed coatings of nanostructured feedstock have shown promise in this direction. Layers of nanostructured yttria stabilized zirconia (nano-YSZ) and conventional YSZ were deposited on\ud mullite substrates using the triple torch plasma reactor (TTPR), and on NiCrAIY coated steel substrates using the\ud Praxair SG-100 plasma torch. The coatings were heat treated and the microstructure evaluated. Heat treating the samples lead to the formation of larger pores with a significant proportion of partially molten particles. The porosity\ud evolved from the partial sintering of the nano -agglomerates. Porosity change during the sintering process was measured and the microstructure observed using electron microscopy. The nanostructured coatings were compared to conventional YSZ coatings