1,426 research outputs found
Fighting Novel Diseases amidst Humanitarian Crises
Humanitarian crises are becoming more prevalent and, frequently, more complex, in zones of mis-governance, lack of government presence, and even active conflict, marked by public mistrust and insecurity. The WHO and other health emergency responders lack the capacities and mandate to adequately respond. The current Ebola outbreak in an area of an active insurgency in the Democratic Republic of the Congo is just such a crisis. The State Department has banned U.S. personnel from the outbreak zone due to safety concerns, leaving the population feeling abandoned, potentially increasing the threat to the few brave health workers who remain.
We need is to rethink health emergency response during complex crises and devise new strategies. We offer a blueprint for responding to health emergencies amidst complex humanitarian crises. This blueprint includes peacekeepers who have the mandate and modalities fit for the purpose of quelling a health emergency; “smart” diplomacy to negotiate with belligerents and community members to ensure health and humanitarian worker safety; and deploying all needed health, security, and diplomatic assets. We also call for international development assistance for health, including to support states in developing core public health capacities, creating inclusive health systems, and meeting other need like clean water and nutritious food. Political actors will need to assume their responsibilities if humanitarians and health workers are to carry out theirs
Design and simulation of thin-film silicon quantum well photovoltaic cell
A new thin-film silicon photovoltaic cell could be designed by inserting quantum well layers in the intrinsic region. Calculations show the improvement in spectral absorption due to the quantum well layer insertion. This article reports the design parameters and enhanced spectral absorption for a newly designed thin-film silicon quantum well photovoltaic cell.
When you are citing the document, use the following link http://essuir.sumdu.edu.ua/handle/123456789/1057
Mill House Refractories
Some of the important aspects involved in designing a furnace relate generally to (I) robustness of construction
(2) ease of control, (3) ease of maintenance and (4) maximum utilisation of heat energy produced in the furn- ace. With a view to ensuring improved performances, the reheating and heat treatment furnaces are now being designed as complicated and precise units In place of simple bricklined boxes, hitherto employed. The demand on the quality of refractories for application in the different zones of such furnaces have become increasingly
stringent
Phosphate bonded monolithics for reheating furnaces
Use of monolithic construction in reheating furnaces for roofs, hearths and burner blocks is gradually on the increase, Phosphate bonded sintered corundum and electro corundum have been reportedly used with considerable
success in U. S. S. R. N. V. Pitak3 etal observed that such ramming mass for the bottoms of soaking pit furnaces
offered high resistances to thermal shock and to action
of ferrunginous 'slag at elevated temperature. According
to S. R. Zamyatin4 etal phosphate bonded fireclay blocks could be recommended for use in blooming soaking pits
Magnetic and structural properties of GeMn films: precipitation of intermetallic nanomagnets
We present a comprehensive study relating the nanostructure of Ge_0.95Mn_0.05
films to their magnetic properties. The formation of ferromagnetic nanometer
sized inclusions in a defect free Ge matrix fabricated by low temperature
molecular beam epitaxy is observed down to substrate temperatures T_S as low as
70 deg. Celsius. A combined transmission electron microscopy (TEM) and electron
energy-loss spectroscopy (EELS) analysis of the films identifies the inclusions
as precipitates of the ferromagnetic compound Mn_5Ge_3. The volume and amount
of these precipitates decreases with decreasing T_S. Magnetometry of the films
containing precipitates reveals distinct temperature ranges: Between the
characteristic ferromagnetic transition temperature of Mn_5Ge_3 at
approximately room temperature and a lower, T_S dependent blocking temperature
T_B the magnetic properties are dominated by superparamagnetism of the Mn_5Ge_3
precipitates. Below T_B, the magnetic signature of ferromagnetic precipitates
with blocked magnetic moments is observed. At the lowest temperatures, the
films show features characteristic for a metastable state.Comment: accepted for publication in Phys. Rev. B 74 (01.12.2006). High
resolution images ibide
Pricing Options in Incomplete Equity Markets via the Instantaneous Sharpe Ratio
We use a continuous version of the standard deviation premium principle for
pricing in incomplete equity markets by assuming that the investor issuing an
unhedgeable derivative security requires compensation for this risk in the form
of a pre-specified instantaneous Sharpe ratio. First, we apply our method to
price options on non-traded assets for which there is a traded asset that is
correlated to the non-traded asset. Our main contribution to this particular
problem is to show that our seller/buyer prices are the upper/lower good deal
bounds of Cochrane and Sa\'{a}-Requejo (2000) and of Bj\"{o}rk and Slinko
(2006) and to determine the analytical properties of these prices. Second, we
apply our method to price options in the presence of stochastic volatility. Our
main contribution to this problem is to show that the instantaneous Sharpe
ratio, an integral ingredient in our methodology, is the negative of the market
price of volatility risk, as defined in Fouque, Papanicolaou, and Sircar
(2000).Comment: Keywords: Pricing derivative securities, incomplete markets, Sharpe
ratio, correlated assets, stochastic volatility, non-linear partial
differential equations, good deal bound
Design and Modeling of Membrane-Based Evaporative Cooling Devices for Thermal Management of High Heat Fluxes
We present a high-heat-flux cooling device for advanced thermal management of electronics. The device incorporates nanoporous membranes supported on microchannels to enable thin-film evaporation. The underlying concept takes advantage of the capillary pressure generated by small pores in the membrane, and minimizes the viscous loss by reducing the membrane thickness. The heat transfer and fluid flow in the device were modeled to determine the effect of different geometric parameters. With the optimization of various parameters, the device can achieve a heat transfer coefficient in excess of 0.05 kW/cm²-K, while dissipating a heat flux of 1 kW/cm². When applied to power electronics, such as GaN high-electron-mobility transistors, this membrane-based evaporative cooling device can lower the near-junction temperature by more than 40 K compared with contemporary single-phase microchannel coolers
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