Dielectric analysis of epoxy/amine resins using microwave cavity technique

Dielectric properties (permittivity and dielectric loss factor) of stoichiometric mixtures of DGEBA (diglycidylether of bisphenol A) epoxy (DER 332) and amine (diaminodiphenyl sulfone; DDS) as a function of temperature and extent of cure have been measured at a microwave frequency of 2.45 GHz. Permittivity and dielectric loss factor of this resin increase with increasing temperature and decrease with increasing extent of cure. Dielectric loss factor is more dependent on temperature in the early stages of cure but becomes less dependent on temperature as the cure proceeds. Dielectric loss data can be related to extent of cure in order to monitor the cure process. Online measurements of temperature- and cure-dependent dielectric loss factor show three material structure stages and significant changes in dielectric loss factor during the microwave cure process. Dielectric Joss factor is also found to be the same for both thermal and microwave cured samples.     

Effects of ultrasonic oscillations on rheological behavior and mechanical properties of novel propylene‐based plastomers

The effects of ultrasonic oscillations on the die pressure, productivity of extrusion, melt apparent viscosity, melt surface appearance, and die swell of novel propylene‐based plastomers were studied in a specially designed ultrasonic oscillations extrusion system developed in our laboratory. The effects of ultrasonic oscillations on molecular weights, tensile strength, and dynamic mechanical properties of extrudates were also studied. The experimental results showed that the presence of ultrasonic oscillations during extrusion could significantly increase the productivity of plastomers at the same die pressure, and reduce die swell and melt fracture such as sharkskin at a given screw rotation speed. The die pressure and apparent viscosity of plastomers remarkably decreased with increasing ultrasonic intensity. Introduction of ultrasonic oscillations into plastomer melts can improve their processibility. The possible mechanism for ultrasonic improvement of rheological behavior was also proposed in this article. Under certain conditions, ultrasound‐assisted extrusion could slightly decrease the glass transition temperature (T_g) and storage modulus of plastomers due to the minor reduction in molecular weights, but showed no significant impact on yield strength and strength at break. © 2007 Wiley Periodicals, Inc. J Appl Polym Sci 2007     

Growth and Application of ZnO Nanostructures

Nanostructures are the building blocks of future nanodevices and thus methods for fabricating nanostructures of various materials in various forms are fundamentally important. Among those nanostructures ZnO has received much attention over the past few years due to the wide range of research by many different groups focused on different novel nanostructures with different properties. Although ZnO nanowires have been intensively studied, there are only a few methods that showed promising characteristics for practical applications. Without much effort, it can be grown in many different nanostructure forms, thus allowing various novel devices to be achieved. In this study, we intend to review those methods that enable nanostructure growth to be more controllable and feasible for applications. The methods for fabricating ZnO nanostructures are introduced in the first part. In the second part, the application of those nanostructures are mentioned and explained. Finally, the future realization of nanodevices is discussed.     

Effect of hydrothermal treatment on the performance of RuO2-Ta2O5/Ti electrodes for use in supercapacitors

Hydrothermal treatment (HTT) of RuO₂-Ta₂O₅/Ti electrode, as a method for improving their performance, for use in supercapacitors was investigated.The results show that HTT significantly enhances the stability of the electrodes. The specific capacitance of electrodes, subject to HTT in the temperature range 180-250 °C remains unchanged after 1000 CV cycles between −0.2 and 1.1 V vs. SCE; without HTT a decay to 97% of the initial is observed. The results also show that HTT decreases the activity of the electrodes for O₂ and H₂ evolution and increases the voltage window by 56-135 mV for supercapacitors, but with a specific capacitance decrease of 7-27%. XPS analyses show the existence of more hydroxides after the HTT, which leads to a little increase in the interplanar distance as indicated in the XDR results. Contact angle measurements show the presence of a more hydrophilic surface after HTT.     

Interlevel dielectric failures in copper/low-k structures

Failure modes for inter-level dielectric layers under accelerated test conditions have been evaluated for a range of dielectric diffusion barriers in copper/low-k structures. The dominant failure mechanism for both constant voltage tests and ramped voltage tests was mechanical cracking at the dielectric barrier/low-k interface. Few occurrences of copper diffusion through the bulk ILD were observed. A simple model for the dominant failure mechanism is proposed which hypothesizes crack formation due to the electrostatic force between interdigitated lines followed by copper extrusion into the cracks. The proposed model is consistent with measurements of interfacial adhesion strengths in Cu/low-k stacks.     

Paired electro-oxidation. I. Production of benzaldehyde

Oxidation of toluene to benzaldehyde by Mn³⁺ and OH free radicals, generated in the anodic and cathodic reactions respectively, was carried out simultaneously in the cathodic and anodic compartments of a cell. The selectivity of benzaldehyde was very high in both the anodic and cathodic reactions. The maximum total current efficiency for benzaldehyde production in the paired electrooxidation was 171%.     

Summary discussion of the 1996 performance assessment for the Waste Isolation Pilot Plant

The Waste Isolation Pilot Plant (WIPP) is under development by the US Department of Energy (DOE) for the geologic disposal of transuranic waste. The construction of complementary cumulative distribution functions (CCDFs) for total radionuclide release from the WIPP to the accessible environment is described. The resultant CCDFs (i) combine releases due to cuttings and cavings, spallings, direct brine release, and long-term transport in flowing groundwater; (ii) fall substantially to the left of the boundary line specified by the US Environmental Protection Agency's (EPA's) standard 40 CFR 191 for the geologic disposal of radioactive waste; and (iii) constitute an important component of the DOE's successful Compliance Certification Application to the EPA for the WIPP. Insights and perspectives gained in the performance assessment (PA) that led to these CCDFs are described, including the importance of: (i) an iterative approach to PA; (ii) uncertainty and sensitivity analysis; (iii) a clear conceptual model for the analysis; (iv) the separation of stochastic (i.e. aleatory) and subjective (i.e. epistemic) uncertainty; (v) quality assurance procedures; (vi) early involvement of peer reviewers, regulators, and stakeholders; (vii) avoidance of conservative assumptions; and (viii) adequate documentation.     

Charge and discharge characteristics of a commercial LiCoO2-based 18650 Li-ion battery

We studied the charge and discharge characteristics of commercial LiCoO₂-based 18650 cells by using various electrochemical methods, including discharging at constant power, ac impedance spectroscopy, and dc-voltage pulse. At 20 °C, these cells deliver 8.7–6.8 Wh of energy when discharged at a power range of 1–12 W between 2.5 and 4.2 V. Ragone plots show that the effect of discharge power on the energy is significantly increased with decreasing of the temperature. For example, energy of the cell is entirely lost when the temperature downs to −10 °C and the discharge rate still remains at 10 W. Impedance analyses indicate that the total cell resistance (R_cell) is mainly contributed by the bulk resistance (R_b, including electric contact resistance and electrolytic ionic conductivity), solid electrolyte interface resistance (R_sei), and charge-transfer resistance (R_ct). Individual contribution of these three resistances to the cell resistance is greatly varied with the temperature. Near room temperature, the R_b occupies up to half of the cell resistance, which means that the rate performance of the cell could be improved by modifying cell design such as employing electrolyte with higher ionic conductivity and enhancing electric contact of the active material particles. At low temperature, the R_ct, which is believed to reflect cell reaction kinetics, dominates the cell resistance. In addition, galvanosatic cycling tests indicate that the charge and discharge processes have nearly same kinetics. The performance discrepancy observed during charging and discharging, especially at low temperatures, can be attributed to these two factors of: (1) substantially higher R_ct at the discharged state than at the charged state; (2) asymmetric voltage limits pre-determined for the charge and discharge processes.     

Annealing effect on the performance of RuO2–Ta2O5/Ti electrodes for use in supercapacitors

The preparation of RuO₂–Ta₂O₅/Ti electrodes, by dip-coating, for use in supercapacitors was investigated. The stability and specific capacitance of the electrodes annealed at various temperatures was examined. The results show that highly stable electrodes with a specific capacitance of 170 F g RuO₂⁻¹ were obtained at approximately 250 °C, while electrodes with a lower capacitance (130 F g RuO₂⁻¹) were obtained at 300 °C. The annealing time needed to obtain a stable RuO₂–Ta₂O₅/Ti electrode at various temperatures correlates well with the Arrhenius’ law: with the activation energy (E) of the annealing reactions for the electrodes being estimated as 73.5 kJ mol⁻¹. SEM images of the electrodes show the coating films to have rough surface morphology with cracks 2–6 μm in width. XRD data indicate that the coating films obtained are composed of crystalline RuO₂ and amorphous tantalum oxide.     

Mesoporous nickel electrodes plated with gold for the detection of glucose

Mesoporous nickel electrodes (MNEs) are efficient structural materials for advanced electrochemical sensors due to their extremely high surface areas. However, the poor oxidation resistance of nano-sized nickel in air severely limits their applications. Thus, the purpose of the present study was to improve the oxidation resistance of MNEs by applying relatively stable gold coatings via electroplating. The results revealed that the gold coatings provided excellent oxidation resistance to MNEs, and a loss in amperometric sensitivity for glucose sensing was not observed. The protection time increased with an increase as the thickness of the gold coating (passing charges of 0–25.49 C/cm²), and protection times ranging from a few hours to 2 weeks were obtained. With an alkaline electrolyte (NaOH, 4 M), MNEs exhibited excellent sensitivities. For instance, the sensitivity of the unmodified MNE and the Au coated-MNE was 3238 and 2978 μA mM⁻¹ cm⁻², respectively. Thus, coated and uncoated MNEs displayed remarkably higher linear sensitivities than conventional nickel-based electrodes (394 μA mM⁻¹ cm⁻²) at a wide range of glucose concentrations (0.001–3 M).