Transracial Adoption: Racial Identity, Resilience, and Self-esteem of African American Adoptees

This study compared self-reported racial identity, resilience, and self-esteem of three independent sample groups consisting of African American adoptees (N = 45), aged 18–72. One group (n = 25) had been adopted by two Caucasian parents, the second (n= 10) by two African American parents, and the third (n = 10) by a single African American parent. The Multidimensional Inventory of Black Identity, Resilience Scale, and Rosenberg Self-esteem Scale were used. Adoptees had higher levels of racial identity when they had been adopted by two African American parents as opposed to two Caucasian parents. Racial identity for adoptees with single African American parents did not differ significantly from either adoptees with two African American parents or adoptees with two Caucasian parents. Resilience was significantly higher for adoptees with two African American parents than for both transracial adoptees and adoptees with a single African American parent. No significant differences regarding self-esteem were found among the three sample groups. As predicted, resilience was positively correlated with racial identity. Contrary to what was hypothesized, resilience and self-esteem had a significant negative correlation. Two, 1-model, hierarchical multiple regression analyses (HMRA) were performed. For the first HMRA, predictor variables accounted for 54% of the variability in self-esteem, with resilience and racial identity negatively correlated with self-esteem. For the second HMRA, predictor variables accounted for 68% of the variability in resilience. Implications of the results, parenting styles of transracial adoptive parents, the author\u27s own White racial identity, and future directions for research are discussed

Thermo-Hydrodynamics of Internally Heated Molten Salts for Innovative Nuclear Reactors

The problem of heat transfer in pipe flow has been extensively investigated in the past. Many different models have been proposed and adopted to predict the velocity profile, the eddy diffusivity, the temperature distributions, the friction factor and the heat transfer coefficient (Kays et al., 2004; Schlichting & Gersten, 2000). However, the majority of such studies give a description of the problem for non-internally heated fluids. Models regarding fluids with internal heat generation have been developed more than 50 years ago (Kinney & Sparrow, 1966; Poppendiek, 1954; Siegel & Sparrow, 1959), giving in most cases a partial treatment of the problem in terms of boundary conditions and heat source distribution, and relying on a turbulent flow treatment that does not seem fully satisfactory in the light of more recent investigations (Churchill, 1997; 2002; Kays, 1994; Zagarola & Smits, 1997). Internally heated fluids are of great interest in the current development of Molten Salt Reactors (MSR) (LeBlanc, 2010), included as one of the six innovative nuclear reactors selected by the Generation IV International Forum (GIF-IV, 2002) for a more sustainable version of nuclear power. MSRs are circulating fuel reactors (Nicolino et al., 2008), which employ a non-classical (fluid-type) fuel constituted by a molten halide (fluoride or chloride) salt mixture playing the distinctive role of both heat source and coolant. By adopting classical correlations for the Nusselt number (e.g., Dittus-Boelter), the heat transfer coefficient of the MSR fuel can be overestimated by a non-negligible amount (Di Marcello et al., 2008). In the case of thermal-neutron-spectrum (graphite-moderated) MSRs (LeBlanc, 2010), this has significant consequences on the core temperature predictions and on the reactor dynamic behaviour (Luzzi et al., 2011). Such influence of the heat source within the fluid cannot be neglected, and thus required proper investigation. The present chapter deals with this critical issue, first summarizing the main modelling efforts carried out by the authors (Di Marcello et al., 2010; Luzzi et al., 2010) to investigate the thermo-hydrodynamics of internally heated fluids, and then focusing on the heat transfer coefficient prediction that is relevant for analysing the molten salt behaviour encountered in MSRs. The chapter is organized as follows. Section 2 provides a brief description of the Molten Salt Reactors, focusing on their distinctive features, in terms of both sustainability (i.e., reduced radioactive waste generation, effective use of natural resources) and safety, with respect to the traditional configuration of nuclear reactors. Section 3 deals with the study of molten salt heat transfer characteristics, which represent a key issue in the current development of MSRs. In particular, a "generalized approach" to evaluate the steady-state temperature distribution in a representative power channel of the reactor core is presented. This approach incorporates recent formulations of turbulent flow and convection (Churchill, 1997; 2002), and is built in order to carefully take into account the molten salt mixture specificities, the reactor core power conditions and the heat transfer in the graphite core structure. In Section 4, a preliminary correlation for the Nusselt number prediction is advanced in the case of simultaneous uniform wall heat flux and internal heat generation, on the basis of the results achieved by means of the presented generalized approach. In Section 5, the main conclusions of the present study are summarized

A perturbation-based susbtep method for coupled depletion Monte-Carlo codes

Coupled Monte Carlo (MC) methods are becoming widely used in reactor physics analysis and design. Many research groups therefore, developed their own coupled MC depletion codes. Typically, in such coupled code systems, neutron fluxes and cross sections are provided to the depletion module by solving a static neutron transport problem. These fluxes and cross sections are representative only of a specific time-point. In reality however, both quantities would change through the depletion time interval. Recently, Generalized Perturbation Theory (GPT) equivalent method that relies on collision history approach was implemented in Serpent MC code. This method was used here to calculate the sensitivity of each nuclide and reaction cross section due to the change in concentration of every isotope in the system. The coupling method proposed in this study also uses the substep approach, which incorporates these sensitivity coefficients to account for temporal changes in cross sections. As a result, a notable improvement in time dependent cross section behavior was obtained. The method was implemented in a wrapper script that couples Serpent with an external depletion solver. The performance of this method was compared with other existing methods. The results indicate that the proposed method requires substantially less MC transport solutions to achieve the same accuracy

Influence of Materials and Packaging Solutions on Thermal Behaviour of Power Modules

Nowadays, designing ever more efficient power modules requires complex materials and more innovative methodologies. To significantly reduce the lead time of the devices and decrease the costs, especially during the prototyping and the testing phases, a Finite Element Analysis (FEA) can be the simplest way to deal with a matrix of parameters to be studied on a single setup. In this work, a thermal characterization is addressed to a stationary simulation using the COMSOL Multiphysics® software, coupling the Heat Transfer Module and the CFD Module. The study is applied to two types of power modules with different technologies, one with Direct Bonded Copper (DBC) substrate and the other one with Insulated Metal Substrate (IMS). An experimental phase follows in order to test the most performing module. A DBC module is composed by (bottom-up) a substrate (copper base, an alumina insulating layer, copper top layer with a specific electrical layout), soldering layers, the dice, the metallic pins, a covering insulating gel and an external protective box. The IMS modules are equal, except for the substrate made up by (bottom-up) a metal base (copper or aluminium), a polymer with ceramic fillers as insulating layer and a copper top layer with the same electrical layout of DBC. The experimental setup used to test real devices is composed by an aluminium water heatsink with a macroscopical copper plate on the top, separated by a thermal grease layer. The device is then mounted on the copper plate with a defined thermal grease layer in between. The geometry considered in the simulation reproduces accurately this experimental setup. The Heat Transfer Module is set to dissipate about 110 W per die. Air natural convection is neglected since it contributes only marginally to the exchange process. This has been assessed with a specific simulation that allows to fix the total insulating condition on the external boundaries, so that only conductive phenomena are considered at this point. The CFD Module is responsible of the water flux entering the heatsink, while the Multiphysics captures the non-isothermal behaviour of the fluid as it flows inside the heatsink. The mesh incorporates different element sizes, depending on the layers thickness. As a result, the FEA solution, provided by COMSOL Multiphysics®, is mostly in accordance with the experimental data. For DBC module, also the packaging is investigated. Different solutions, such as Vacuum Potting Gel (VPG), are applied to the standard module, analysing thermal resistance and heat dissipation. As an example, the VPG solution consists in filling a protective plastic case with a silicone dielectric gel. The layers disposition is precisely the one described in the DBC section above. The modules are imported in the software and placed upon the testing setup already in use for the previous part. The simulations return interesting insight in the thermal behaviour of the modules

Mapping job complexity and skills into wages

We use algorithmic and network-based tools to build and analyze the bipartite network connecting jobs with the skills they require. We quantify and represent the relatedness between jobs and skills by using statistically validated networks. Using the fitness and complexity algorithm, we compute a skill-based complexity of jobs. This quantity is positively correlated with the average salary, abstraction, and non-routinarity level of jobs. Furthermore, coherent jobs - defined as the ones requiring closely related skills - have, on average, lower wages. We find that salaries may not always reflect the intrinsic value of a job, but rather other wage-setting dynamics that may not be directly related to its skill composition. Our results provide valuable information for policymakers, employers, and individuals to better understand the dynamics of the labor market and make informed decisions about their careers

Development of a Reduced Order Model for Fuel Burnup Analysis

Fuel burnup analysis requires a high computational cost for full core calculations, due to the amount of the information processed for the total reaction rates in many burnup regions. Indeed, they reach the order of millions or more by a subdivision into radial and axial regions in a pin-by-pin description. In addition, if multi-physics approaches are adopted to consider the effects of temperature and density fields on fuel consumption, the computational load grows further. In this way, the need to find a compromise between computational cost and solution accuracy is a crucial issue in burnup analysis. To overcome this problem, the present work aims to develop a methodological approach to implement a Reduced Order Model (ROM), based on Proper Orthogonal Decomposition (POD), in fuel burnup analysis. We verify the approach on 4 years of burnup of the TMI-1 unit cell benchmark, by reconstructing fuel materials and burnup matrices over time with different levels of approximation. The results show that the modeling approach is able to reproduce reactivity and nuclide densities over time, where the accuracy increases with the number of basis functions employed

A prática inquisitorial no Brasil: história e contemporaneidade

Este artigo analisa o inquérito policial, seu fluxo e resultados. A finalidade do inquérito será sempre a de fornecer oselementos necessários para formar a suspeita do crime, integrando-se os elementos investigatórios para que a açãopenal proposta seja aceita ou não. Todavia, um percentual significativo de inquéritos policiais enviados ao MinistérioPúblico tem retornado às delegacias para novas investigações, ou mesmo para que sejam anexados laudos quedeveriam constar neste. Na ausência de recursos técnicos que permitam determinar provas de culpa, muitos inquéritossão rejeitados

Oneiric stress and safety and security at work: the discovery of a new universal symbol

Cox and Griffiths define as psychosocial risks at work “those aspects of the planning, organization and management of work, which, along with their environmental and social contexts, may affect mental and physical health of the employees, directly or indirectly producing stress”. Therefore, a more effective approach to occupational safety and security should include integrated risk management through the identification of any work stress related problem. The purpose of this paper is to analyze the possible correlation of risk at work with the modification of sleep, and inside it, the specific function of dream activity