363 research outputs found
Enabling electronic prognostics using thermal data
Prognostics is a process of assessing the extent of deviation or degradation
of a product from its expected normal operating condition, and then, based on
continuous monitoring, predicting the future reliability of the product. By
being able to determine when a product will fail, procedures can be developed
to provide advanced warning of failures, optimize maintenance, reduce life
cycle costs, and improve the design, qualification and logistical support of
fielded and future systems. In the case of electronics, the reliability is
often influenced by thermal loads, in the form of steady-state temperatures,
power cycles, temperature gradients, ramp rates, and dwell times. If one can
continuously monitor the thermal loads, in-situ, this data can be used in
conjunction with precursor reasoning algorithms and stress-and-damage models to
enable prognostics. This paper discusses approaches to enable electronic
prognostics and provides a case study of prognostics using thermal data.Comment: Submitted on behalf of TIMA Editions
(http://irevues.inist.fr/tima-editions
A decomposition-based design optimization method with applications
A two-level design optimization metholology is described. A progress report of its application to Printed Wiring Board (PWB) assembly examples is given. The design of PWB assemblies is a complex task which is generally conducted as a sequential process. Individual PWBs are usually designed first, followed by the composition of the PWBs into an assembly. As a result, optimizing design considerations such as assembly reliability cannot be accomplished. This study showed that a two-level decomposition method can be employed to optimize for reliability at both the PWB- and the assembly-level in a coupled manner. The two-level decomposition method also resolved the mixed-integer nonlinear programming nature of the problem rather easily
Electron Transfer Reactivity of Type Zero Pseudomonas aeruginosa Azurin
Type zero copper is a hard-ligand analogue of the classical type 1 or blue site in copper proteins that function as electron transfer (ET) agents in photosynthesis and other biological processes. The EPR spectroscopic features of type zero Cu^(II) are very similar to those of blue copper, although lacking the deep blue color, due to the absence of thiolate ligation. We have measured the rates of intramolecular ET from the pulse radiolytically generated C3−C26 disulfide radical anion to the Cu^(II) in both type zero C112D/M121L and type 2 C112D Pseudomonas aeruginosa azurins in pH 7.0 aqueous solutions between 8 and 45 °C. We also have obtained rate/temperature (10−30 °C) profiles for ET reactions between these mutants and the wild-type azurin. Analysis of the rates and activation parameters for both intramolecular and intermolecular ET reactions indicates that the type zero copper reorganization energy falls in a range (0.9−1.1 eV) slightly above that for type 1 (0.7−0.8 eV), but substantially smaller than that for type 2 (>2 eV), consistent with XAS and EXAFS data that reveal minimal type zero site reorientation during redox cycling
Ceramic Substrates for High-temperature Electronic Integration
One of the most attractive ways to increase power handling capacity in power modules is to increase the operating temperature using wide-band-gap semiconductors. Ceramics are ideal candidates for use as substrates in high-power high-temperature electronic devices. The present article aims to determine the most suitable ceramic material for this application
Safety Requirements for Transportation of Lithium Batteries
The demand for battery-powered products, ranging from consumer goods to electric vehicles, keeps increasing. As a result, batteries are manufactured and shipped globally, and the safe and reliable transport of batteries from production sites to suppliers and consumers, as well as for disposal, must be guaranteed at all times. This is especially true of lithium batteries, which have been identified as dangerous goods when they are transported. This paper reviews the international and key national (U.S., Europe, China, South Korea, and Japan) air, road, rail, and sea transportation requirements for lithium batteries. This review is needed because transportation regulations are not consistent across countries and national regulations are not consistent with international regulations. Comparisons are thus provided to enable proper and cost-effective transportation; to aid in the testing, packaging, marking, labelling, and documentation required for safe and reliable lithium cell/battery transport; and to help in developing national and internal policies.https://doi.org/10.3390/en1006079
Marked changes in electron transport through the blue copper protein azurin in the solid state upon deuteration
Measuring electron transport (ETp) across proteins in the solid-state offers
a way to study electron transfer (ET) mechanism(s) that minimizes solvation
effects on the process. Solid state ETp is sensitive to any static
(conformational) or dynamic (vibrational) changes in the protein. Our
macroscopic measurement technique extends the use of ETp meas-urements down to
low temperatures and the concomitant lower current densities, because the
larger area still yields measurable currents. Thus, we reported previously a
surprising lack of temperature-dependence for ETp via the blue copper protein
azurin (Az), from 80K till denaturation, while ETp via apo-(Cu-free) Az was
found to be temperature de-pendent \geq 200K. H/D substitution (deuteration)
can provide a potentially powerful means to unravel factors that affect the ETp
mechanism at a molecular level. Therefore, we measured and report here the
kinetic deuterium isotope effect (KIE) on ETp through holo-Az as a function of
temperature (30-340K). We find that deuteration has a striking effect in that
it changes ETp from temperature independent to temperature dependent above
180K. This change is expressed in KIE values between 1.8 at 340K and 9.1 at
\leq 180K. These values are particularly remarkable in light of the previously
reported inverse KIE on the ET in Az in solution. The high values that we
obtain for the KIE on the ETp process across the protein monolayer are
consistent with a transport mechanism that involves
through-(H-containing)-bonds of the {\beta}-sheet structure of Az, likely those
of am-ide groups.Comment: 15 pages, 3 figures, 2 Supplementary figure
Coherent Electron Transport across a 3 nm Bioelectronic Junction Made of Multi-Heme Proteins
Multi-heme cytochromes (MHCs) are fascinating proteins used by bacterial organisms to shuttle electrons within, between, and out of their cells. When placed in solid-state electronic junctions, MHCs support temperature-independent currents over several nanometers that are 3 orders of magnitude higher compared to other redox proteins of similar size. To gain molecular-level insight into their astonishingly high conductivities, we combine experimental photoemission spectroscopy with DFT+Σ current-voltage calculations on a representative Gold-MHC-Gold junction. We find that conduction across the dry, 3 nm long protein occurs via off-resonant coherent tunneling, mediated by a large number of protein valence-band orbitals that are strongly delocalized over heme and protein residues. This picture is profoundly different from the electron hopping mechanism induced electrochemically or photochemically under aqueous conditions. Our results imply that the current output in solid-state junctions can be even further increased in resonance, for example, by applying a gate voltage, thus allowing a quantum jump for next-generation bionanoelectronic devices
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