A Thermal Plume Model for the Martian Convective Boundary Layer

The Martian Planetary Boundary Layer [PBL] is a crucial component of the Martian climate system. Global Climate Models [GCMs] and Mesoscale Models [MMs] lack the resolution to predict PBL mixing which is therefore parameterized. Here we propose to adapt the "thermal plume" model, recently developed for Earth climate modeling, to Martian GCMs, MMs, and single-column models. The aim of this physically-based parameterization is to represent the effect of organized turbulent structures (updrafts and downdrafts) on the daytime PBL transport, as it is resolved in Large-Eddy Simulations [LESs]. We find that the terrestrial thermal plume model needs to be modified to satisfyingly account for deep turbulent plumes found in the Martian convective PBL. Our Martian thermal plume model qualitatively and quantitatively reproduces the thermal structure of the daytime PBL on Mars: superadiabatic near-surface layer, mixing layer, and overshoot region at PBL top. This model is coupled to surface layer parameterizations taking into account stability and turbulent gustiness to calculate surface-atmosphere fluxes. Those new parameterizations for the surface and mixed layers are validated against near-surface lander measurements. Using a thermal plume model moreover enables a first order estimation of key turbulent quantities (e.g. PBL height, convective plume velocity) in Martian GCMs and MMs without having to run costly LESs.Comment: 53 pages, 21 figures, paper + appendix. Accepted for publication in Journal of Geophysical Research - Planet

C2PA, a new protein expressed during mouse spermatogenesis

AbstractC2PA is a novel protein that contains a C2 membrane binding domain, a PDZ protein/protein interaction domain, and an ATP/GTP binding domain. C2PA is expressed during embryogenesis from 8.5 days post-coitum (dpc) until birth. After birth, C2PA expression is mainly observed in the post-natal and adult testis. During spermatogenesis, C2PA transcripts are specifically observed in the spermatocytes, whereas spermatogonia and spermatids are negative. Taken together, these results suggest that C2PA might be involved in cell signaling pathways occurring during spermatogenesis

Design of novel γ’ bondcoats and interdiffusion with Re-rich superalloys

Increasing the life of thermal barrier coating (TBC) systems critically relies on maintaining good adhesion between the bondcoat, the thermally grown oxide (TGO) and the topcoat. A common cause of failure, rumpling occurs as stress generated by oxide growth and thermal cycling results in creep of the mechanically weak bondcoat – this currently limits the life of EB-PVD TBCs with β coatings used in aircraft turbine blades and vanes. γ’ coatings are known to present a better creep strength than β coatings and thereby markedly reduce rumpling, while still offering adequate oxidation resistance. The higher solubility of reactive elements (RE) in γ’ also provides more flexibility in optimizing RE additions, as it limits the risk of overdoping; this can be used to further improve TGO adhesion. Furthermore, γ’ compositions can, by essence, be adjusted to reduce the chemical potential mismatch with the substrate; this in turn will help curb the development of secondary reaction zones, which have become an issue when β coatings are used on Re-containing superalloys. The poster will present recent efforts made at ONERA in the development of new γ’ compositions for Re-rich substrates. Our current design strategy focuses on limiting substrate-coating interdiffusion and the associated loss of load-bearing section in the alloy. As mechanical properties improve and the bondcoat Al content is reduced, however, the bondcoat ability to maintain exclusive Al2O3 formation throughout extended cycling becomes critical to the system durability. Coating compositions are thus adjusted to a given alloy following the “equilibrium coating” concept, and then slightly modified to help maintain an appropriate composition relative to oxidation resistance. Compositions are assessed through the study of interdiffusion profiles obtained from both experiments and numerical simulations via a finite-difference method

Legal Services Assessment for Trafficked Children- Cook County, Illinois Case Study

Child trafficking is one of the most disturbing human rights abuses of our time, involving cases of boys and girls exploited for labor and/or commercial sexual services. These children may suffer physical, sexual, and emotional violence at the hands of traffickers, who can be pimps, employers, and even family members. Trafficking schemes may involve various forms of force, fraud, and coercion, which can be physical and/or psychological in nature. Current research indicates that legal services are a critical component of a comprehensive service delivery model for victims of human trafficking and a realization of human rights. However, little to no effort has been made to identify the various legal needs of child trafficking victims, a particularly vulnerable population. In February 2012, the Center for the Human Rights of Children (CHRC) initiated a legal needs assessment project for child trafficking victims, using Cook County Illinois as a case study. The project identified: •Existing service providers working with both US citizen and foreign national child trafficking survivors •The legal needs of trafficked children •Current legal services available to this population •Gaps in those services in Cook County We chose Cook County as a case study for several reasons. It is the second most populous county in the nation, and houses the city of Chicago, which has been recognized as one several human trafficking hubs across the United States. Cook County has an established community of service providers and advocacy organizations working with survivors of human trafficking in various capacities, and two task forces. The project also included a preliminary assessment of legal services for child trafficking victims offered by organizations around the country as a comparison to the results of our research in Cook County

Tumor Necrosis Factor Receptor-Associated Factor 4 Is a Dynamic Tight Junction-Related Shuttle Protein Involved in Epithelium Homeostasis

BACKGROUND: Despite numerous in vivo evidences that Tumor Necrosis Factor Receptor-Associated Factor 4 (TRAF4) plays a key biological function, how it works at the cellular and molecular level remains elusive. METHODOLOGY/PRINCIPAL FINDINGS: In the present study, we show using immunofluorescence and immuohistochemistry that TRAF4 is a novel player at the tight junctions (TJs). TRAF4 is connected to assembled TJs in confluent epithelial cells, but accumulates in the cytoplasm and/or nucleus when TJs are open in isolated cells or EGTA-treated confluent cells. In vivo, TRAF4 is consistently found at TJs in normal human mammary epithelia as well as in well-differentiated in situ carcinomas. In contrast, TRAF4 is never localized at the plasma membrane of poorly-differentiated invasive carcinomas devoid of correct TJs, but is observed in the cytoplasm and/or nucleus of the cancer cells. Moreover, TRAF4 TJ subcellular localization is remarkably dynamic. Fluorescence recovery after photobleaching (FRAP) experiments show that TRAF4 is highly mobile and shuttles between TJs and the cytoplasm. Finally, we show that intracellular TRAF4 potentiates ERK1/2 phosphorylation in proliferating HeLa cells, an epithelial cell line known to be devoid of TJs. CONCLUSIONS/SIGNIFICANCE: Collectively, our data strongly support the new concept of TJs as a dynamic structure. Moreover, our results implicate TRAF4 in one of the emerging TJ-dependent signaling pathways that responds to cell polarity by regulating the cell proliferation/differentiation balance, and subsequently epithelium homeostasis. Drastic phenotypes or lethality in TRAF4-deficient mice and drosophila strongly argue in favor of such a function

Revisiting Maya Blue and Designing Hybrid Pigments by Archaeomimetism

Maya Blue is actually one of the best known examples of an organic-inorganic hybrid material. Yet despite 50 years of sustained interest, its microscopic structure and its relation to durability remain open questions. We address the issue by archaeomimetism: engineering an archaeoinspired pigment, satisfactorily reproducing the colour and chemical stability of Maya Blue. By comparing and contrasting ancient pigment and the new analogue, we deduce a new explanation for this durability