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Volume 30(9); September 2017

An Electrical Properties Analysis of CMOS IC by Narrow-Band High-Power Electromagnetic Wave
Jin-wook Park, Chang-su Huh, Chang-su Seo, Sung-woo Lee
J Electr Electron Mater 2017;30(9):535-540.   Published online September 1, 2017
The changes in the electrical characteristics of CMOS ICs due to coupling with a narrow-band electromagnetic wave were analyzed in this study. A magnetron (3 kW, 2.45 GHz) was used as the narrow-band electromagnetic source. The DUT was a CMOS logic IC and the gate output was in the ON state. The malfunction of the ICs was confirmed by monitoring the variation of the gate output voltage. It was observed that malfunction (self-reset) and destruction of the ICs occurred as the electric field increased. To confirm the variation of electrical characteristics of the ICs due to the narrow-band electromagnetic wave, the pin-to-pin resistances (Vcc-GND, Vcc-Input1, Input1-GND) and input capacitance of the ICs were measured. The pin-to-pin resistances and input capacitance of the ICs before exposure to the narrow-band electromagnetic waves were 8.57 MΩ (Vcc-GND), 14.14 MΩ (Vcc-Input1), 18.24 MΩ (Input1-GND), and 5 pF (input capacitance). The ICs exposed to narrow-band electromagnetic waves showed mostly similar values, but some error values were observed, such as 2.5 Ω, 50 MΩ, or 71 pF. This is attributed to the breakdown of the pn junction when latch-up in CMOS occurred. In order to confirm surface damage of the ICs, the epoxy molding compound was removed and then studied with an optical microscope. In general, there was severe deterioration in the PCB trace. It is considered that the current density of the trace increased due to the electromagnetic wave, resulting in the deterioration of the trace. The results of this study can be applied as basic data for the analysis of the effect of narrow-band high-power electromagnetic waves on ICs.
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Phase Evolution and Electrical Properties of PZT Films by Aerosol-Deposition Method
Chun-kil Park, Dong-kyun Kang, Seung-hee Lee, Young-min Kong, Dae-yong Jeong
J Electr Electron Mater 2017;30(9):541-550.   Published online September 1, 2017
Pb(Zr0.52Ti0.48)O3 (PZT) films with a thickness of 5~10 μm at the morphotropic phase boundary were fabricated by aerosol-deposition (AD), and their phase evolution and electrical properties were investigated. The microstructure of the AD PZT films revealed nanosized grains with a low crystallinity and a dense structure at room temperature. The AD PZT films showed a mixture of tetragonal and rhombohedral phases. The post-annealing temperature was varied to study the phase transition behavior. The crystallinity of the AD PZT films was enhanced by annealing at 450, 550, and 650℃ for 2 h. At 650℃, the tetragonal and rhombohedral phases reacted to form a bridge phase between the two phases. The polarization-electric field hysteresis loops of the AD PZT film annealed at 650℃ exhibited a smaller cohesive field and a lower slim hysteresis than the films annealed at 450 and 550℃.
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Ferroelastic Domain Wall Motions in Lead Zirconate Titanate Under Compressive Stress Observed by Piezoresponse Force Microscopy
Kwanlae Kim
J Electr Electron Mater 2017;30(9):546-550.   Published online September 1, 2017
Ferroelectric properties are governed by domain structures and domain wall motions, so it is of significance to understand domain evolution processes under mechanical stress. In the present study, in situ piezoresponse force microscopy (PFM) observation under compressive stress was carried out for a near-morphotropic PZT. Both 180° and non-180° domain structures were observed from PFM images, and their habit planes were identified using electron backscatter diffraction in conjunction with PFM data. By externally applied mechanical stress, needle-like non-180° domain patterns were broadened via domain wall motions. This was interpreted via phenomenological approach such that the total energy minimization can be achieved by domain wall motion rather than domain nucleation mainly due to the local gradient energy. Meanwhile, no motion was observed from curvy 180° domain walls under the mechanical stress, validating that 180° domain walls are not directly influenced by mechanical stress.
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Lifetime Assessments on 154 kV Transmission Porcelain Insulators with a Bayesian Approach
In-hyuk Choi, Tae-kyun Kim, Yong-beum Yoon, Junsin Yi, Seong Wook Kim
J Electr Electron Mater 2017;30(9):551-557.   Published online September 1, 2017
It is extremely important to improve methodologies for the lifetime assessment of porcelain insulators. While there has been a considerable amount of work regarding the phenomena of lifetime distributions, most of the studies assume that aging distributions follow the Weibull distribution. However, the true underlying distribution is unknown, giving rise to unrealistic inferences, such as parameter estimations. In this article, we review several distributions that are commonly used in reliability and survival analysis, such as the exponential, Weibull, log-normal, and gamma distributions. Some properties, including the characteristics of failure rates of these distributions, are presented. We use a Bayesian approach for model selection and parameter estimation procedures. A well-known measure, called the Bayes factor, is used to find the most plausible model among several contending models. The posterior mean can be used as a parameter estimate for unknown parameters, once a model with the highest posterior probability is selected. Extensive simulation studies are performed to demonstrate our methodologies.
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Effect of Porcelain/Polymer Interface on the Microstructure, Insulation Characteristics and Electrical Field Distribution of Hybrid Insulators
Jun-young Cho, Woo-seok Kim, Ho-sung An, Hee-sung An, Tae-wan Kim, Yun-seog Lim, Sung-hwan Bae, Chan Park
J Electr Electron Mater 2017;30(9):558-565.   Published online September 1, 2017
Hybrid insulators that have the advantages of both porcelain (high mechanical strength and chemical stability) as well as polymer (light weight and high resistance to pollution) insulators, can be used in place of individual porcelain and polymer insulators that are used for both mechanical support as well as electrical insulation of overhead power transmission lines. The most significant feature of hybrid insulators is the presence of porcelain/polymer interfaces where the porcelain and polymer are physically bonded. Individual porcelain and polymer insulators do not have such porcelain/polymer interfaces. Although the interface is expected to affect the mechanical/electrical properties of the hybrid insulator, systematic studies of the adhesion properties at the porcelain/polymer interface and the effect of the interface on the insulation characteristics and electric field distribution of the hybrid insulator have not been reported. In this study, we fabricated small hybrid insulator specimens with various types of interfaces and investigated the effect of the porcelain/polymer interface on the microstructure, insulating characteristics, and electric field distribution of the hybrid insulators. It was observed that the porcelain/polymer interface of the hybrid insulator does not have a significant effect on the insulating characteristics and electric field distribution, and the hybrid insulator can exhibit electrical insulating properties that are similar or superior to those of individual porcelain and polymer insulators.
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Improvement in Electrical Characteristics of Solution-Processed In-Zn-O Thin-Film Transistors Using a Soft Baking Process
Han-sang Kim, Sung-jin Kim
J Electr Electron Mater 2017;30(9):566-571.   Published online September 1, 2017
A soft baking process was used to enhance the electrical characteristics of solution-processed indium-zincoxide (IZO) thin-film transistors (TFTs). We demonstrate a stable soft baking process using a hot plate in air to maintain the electrical stability and improve the electrical performance of IZO TFTs. These oxide transistors exhibited good electrical performance; a field-effect mobility of 7.9 cm2/Vs, threshold voltage of 1.4 V, sub-threshold slope of 0.5 V/dec, and a current on/off ratio of 2.9×107 were measured. To investigate the static response of our solutionprocessed IZO TFTs, simple resistor load type inverters were fabricated by connecting a resistor (5 or 10 MΩ). Our IZO TFTs, which were manufactured using the soft baking process at a baking temperature of 120℃, performed well at the operating voltage, and are therefore a good candidate for use in advanced logic circuits and transparent display backplanes.
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Fabrication of Graphene/Silver Nanowire Hybrid Electrodes via Transfer Printing of Graphene
Bonhee Ha, Sungjin Joa
J Electr Electron Mater 2017;30(9):572-576.   Published online September 1, 2017
A hybrid transparent electrode was fabricated with graphene and silver nanowires (Ag NWs). Three different processes were used to fabricate the hybrid electrode. Measurements of the sheet resistances, transmittances, and surface roughnesses of the hybrid electrodes were used to identify the optimal fabrication process. The surface roughness of the hybrid electrodes with Ag NWs embedded in a transparent polymer matrix was significantly lower than that of the other hybrid electrodes. A hybrid electrode fabricated by transferring graphene onto Ag NWs after spin-coating the Ag NWs onto the substrate showed the lowest sheet resistance. The transmittance of the hybrid electrodes was comparable to that of Ag NW electrodes.
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Synthesis and Characterization of Red Organic Fluorescent of Perylene Bisimide Derivatives
Seung Min Lee, Yeon Tae Jeong
J Electr Electron Mater 2017;30(9):577-582.   Published online September 1, 2017
The white light of a hybrid LED is obtained by using red and green organic fluorescent layers made of polymethylmethacrylate (PMMA) films, which function as color down-conversion layers of blue light-emitting diodes. In this research, we studied the fluorescence properties of a red organic fluorophore, employing perylene bisimide derivatives applicable to hybrid LEDs. The solubility, thermal stability, and luminous efficiency are important characteristics of organic fluorophores for use in hybrid LEDs. The perylene fluorescent compounds (1A and 1B) were prepared by the reaction of 4-bromophenol and 4-iodophenol with N,N`-bis(4-bromo-2,6-diisopropylphenyl)-1, 6,7,12-tetrachloroperylene-3,4,9,10-tetracarboxyl diimide (1) in the presence of dimethyl formaldehyde (DMF) at 70℃. The synthesized derivatives were characterized by using 1H-NMR, FT-IR, UV/Vis absorption and PL spectra, and TGA analysis. Compounds 1A and 1B showed absorption and emission at 570 nm and 604 nm in the UV/Vis spectrum. We also documented favorable solubility and thermal stability characteristics of the perylene fluorophores in our work. Perylene fluorophore 1, with the 4-bromophenol substituent 1A, exhibited particularly good thermal stability and solubility in organic solvents.
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Effect of Cathode Materials (MS2, M=Fe, Ni, Co) on Electrochemical Properties of Thermal Batteries
Jungmin Lee, Chae-nam Im, Hyun-ki Yoon, Hae-won Cheong
J Electr Electron Mater 2017;30(9):583-588.   Published online September 1, 2017
Thermal batteries are used in military power sources that require robustness and long storage life for applications in missiles and torpedoes. FeS2 powder is currently used as a cathode material because of its high specific energy density, environmental non-toxicity, and low cost. MS2 (M = Fe, Ni, Co) cathodes have been explored as novel candidates for thermal batteries in many studies; however, the discharge characteristics (1, 2, 3 plateau) of single cells in thermal batteries with different cathodes have not been elucidated in detail. In this study, we independently analyzed the discharge voltage and calculated the total polarizations of single cells using MS2 cathodes. Based on the results of this study, we propose NiS2 as a potential cathode material for use in thermal batteries.
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Heat Energy Diffusion Analysis in the Gas Sensor Body with the Variation of Drain-Source Electrode Distance
Kyung-uk Jang
J Electr Electron Mater 2017;30(9):589-595.   Published online September 1, 2017
MOS-FET structured gas sensors were manufactured using MWCNTs for application as NOx gas sensors. As the gas sensors need to be heated to facilitate desorption of the gas molecules, heat dispersion plays a key role in boosting the degree of uniformity of molecular desorption. We report the desorption of gas molecules from the sensor at 150℃ for different sensor electrode gaps (30, 60, and 90 μm). The COMSOL analysis program was used to verify the process of heat dispersion. For heat analysis, structure of FET gas sensor modeling was proceeded. In addition, a property value of the material was used for two-dimensional modeling. To ascertain the degree of heat dispersion by FEM, the governing equations were presented as partial differential equations. The heat analysis revealed that although a large electrode gap is advantageous for effective gas adsorption, consideration of the heat dispersion gradient indicated that the optimal electrode gap for the sensor is 60 μm.
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Development of Moving and Attaching Diagnosis Device Using IoT
Chool-hyun Ka, Dong-gyu Lee, Jin-sa Kim
J Electr Electron Mater 2017;30(9):596-601.   Published online September 1, 2017
The advancement and diversification of urban functions has caused an increasing need to improve the reliability of power supplies. The diversification of urban areas causes social disruptions by paralyzing urban functions during power outages. A large power outage occurs in the event of an accident, owing to the subduction of distribution lines. Therefore, in recent years, for the sake of the environment and safety, the safety diagnosis of electric power facilities has become an important issue. In this system, because thermal information changes rapidly during unattended monitoring owing to heat concentration phenomenon due to abnormal load or deterioration, studies have been conducted on the development of a device that can notify the manager at all times.
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Development of Multiple Wireless Communication Controller for Smart Factory Construction
Jae-jun Oh, Seong-ju Choi, Jin-sa Kim
J Electr Electron Mater 2017;30(9):602-608.   Published online September 1, 2017
Due to recent industry 4.0, manufacturing has changed a lot. In particular, it is necessary to control the controller and controller of the control system, to communicate various production information and measurement information, and to produce a database in accordance with the flexible production for a small quantity of various items, and to manage the trend of major parts of production facilities. In this paper, we developed a multiple wireless communication controller for small scale control system for smart factory by applying XBee and microcomputer. This controller is cheap and easy to build multi-radio communication environment of 1: N and can control and monitor control system. In addition, we tested multiple wireless communication controllers by using signal processing device and C++, and constructed network, control, and database for mechanism module, and confirmed effectiveness for industrial application.
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