Town of Hancock Maine Ordinances

Ordinances cover: Environmental Control; Floodplain Management; Mineral Extraction; Mobile Home Park; Subdivision; Water Extractio

Examination of Ni-based superalloy/intermetallic diffusion couples containing multiphase regions

Increasing gas turbine operating temperatures are driving the development of novel coatings for niche applications. One such application is as an anchor phase material for use in the high-pressure turbine stage, for which NiAlTa alloys are a promising candidate. Extended exposure to the high temperatures of this environment can cause interdiffusion of elements between the coating and the underlying blade material. In this study, NiAlTa/CMSX-4 diffusion couples were investigated experimentally and computationally. The couples initially contained two two-phase regions (γ + γ′) and (β + τ1). After heat treatment at 1100 °C, interdiffusion had caused the τ1 Laves phase in the coating to transform to the τ2 Heusler phase, and TCP precipitation was observed in the CMSX-4. A CALPHAD-based model, using Thermo-Calc and DICTRA, developed for this system was able to predict the concentration profiles across the diffusion couple at 1000 °C, with the presence of the predicted phases in the interdiffusion zone verified by x-ray diffraction. However, due to the limited diffusion data for intermetallic phases available in the kinetic database, the model predictions were poor at higher temperatures. In order for the development of intermetallic coatings to be aided by CALPHAD-based simulations, more kinetic data is needed for intermetallic phases than is available at present

Mechanics and dynamics of X-chromosome pairing at X inactivation

At the onset of X-chromosome inactivation, the vital process whereby female mammalian cells equalize X products with respect to males, the X chromosomes are colocalized along their Xic (X-inactivation center) regions. The mechanism inducing recognition and pairing of the X’s remains, though, elusive. Starting from recent discoveries on the molecular factors and on the DNA sequences (the so-called "pairing sites") involved, we dissect the mechanical basis of Xic colocalization by using a statistical physics model. We show that soluble DNA-specific binding molecules, such as those experimentally identified, can be indeed sufficient to induce the spontaneous colocalization of the homologous chromosomes but only when their concentration, or chemical affinity, rises above a threshold value as a consequence of a thermodynamic phase transition. We derive the likelihood of pairing and its probability distribution. Chromosome dynamics has two stages: an initial independent Brownian diffusion followed, after a characteristic time scale, by recognition and pairing. Finally, we investigate the effects of DNA deletion/insertions in the region of pairing sites and compare model predictions to available experimental data

Detection of Extensive Cross-Neutralization between Pandemic and Seasonal A/H1N1 Influenza Viruses Using a Pseudotype Neutralization Assay

BACKGROUND: Cross-immunity between seasonal and pandemic A/H1N1 influenza viruses remains uncertain. In particular, the extent that previous infection or vaccination by seasonal A/H1N1 viruses can elicit protective immunity against pandemic A/H1N1 is unclear. METHODOLOGY/PRINCIPAL FINDINGS: Neutralizing titers against seasonal A/H1N1 (A/Brisbane/59/2007) and against pandemic A/H1N1 (A/California/04/2009) were measured using an HIV-1-based pseudovirus neutralization assay. Using this highly sensitive assay, we found that a large fraction of subjects who had never been exposed to pandemic A/H1N1 express high levels of pandemic A/H1N1 neutralizing titers. A significant correlation was seen between neutralization of pandemic A/H1N1 and neutralization of a standard seasonal A/H1N1 strain. Significantly higher pandemic A/H1N1 neutralizing titers were measured in subjects who had received vaccination against seasonal influenza in 2008-2009. Higher pandemic neutralizing titers were also measured in subjects over 60 years of age. CONCLUSIONS/SIGNIFICANCE: Our findings reveal that the extent of protective cross-immunity between seasonal and pandemic A/H1N1 influenza viruses may be more important than previously estimated. This cross-immunity could provide a possible explanation of the relatively mild profile of the recent influenza pandemic