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"Reflectivity"

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"Reflectivity"

For electronic paper displays using electrophoresis, the response time and reflectivity of the image panel fabricated by filtering are analyzed. For the filtering process, a square wave and ramp wave are applied to white charged particles with a unique q/m value. We divide the sample panels into #1 to #4 according to the applied waveform in the filtering process. Step waves comprising two steps are used to drive the panel; therefore, we divide the driving conditions into D1~D4. The applied voltage at the first stage of the half cycle of the driving waveform moves the charged particles attached via the image force from the electrode, and the applied voltage at the second stage moves the floating charged particles by detaching. As mentioned, four types of driving conditions (D1 to D4) classified according to the half cycle of the driving waveform are applied to the samples #1 to #4), which are classified according to four types of filtering process. When driving condition D1 is applied to the four types of sample panels, the rise time of #1 is 1.59s, #2 is 1.706s, #3 is 1.853s, and #4 is 1.235s, resulting in #4 being relatively faster compared with other sample panels, and showing the same trend in other driving conditions. As a result, we confirm that applying the driving condition D1 causes abrupt movement of the white charged particles injected into the cell. When the same driving waveform (D1) is applied to each sample, reflectivities of 32.1% for #1, 31.4% for #2, 27.9% for #3, and 63.4% for #4 are measured. From the experiment, we confirm that the driving condition D1 (1s of 3.5 V, 9s of 3.0 V) and ramp wave #4 in filtering are desirable for good reflectivity and response time. Our research is expected to contribute to the improvement of the filtering process and optimization of the driving waveform.
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Sintering and the Optical Properties of Mn3O4-added Al2O3
Jin-ho Kim, Seung-woo Baik
J Electr Electron Mater 2016;29(9):539-545.   Published online September 1, 2016
Alumina added with Mn3O4 up to 7.5 cat% of Mn was prepared by conventional ceramic processing, and the sintering behavior and the optical properties of which were studied as functions of Mn content. Densification and grain growth of alumina were enhanced by Mn addition up to 0.75 cat% but was leveled off at higher concentrations. XRD revealed that Al2MnO4(galaxite) was formed as a second phase in the specimens with more than 0.75 cat% of Mn. Thus it is believed that either the solid solution effect of Mn or the Zener effect of Al2MnO4 becomes predominant in the sintering of Mn-added Al2O3 according to the additive concentration. UV-VIS reflectivity(SCI) spectra of Mn-added Al2O3 consisted of smooth bottoms in 300~550 nm wavelength range and plateaus at wavelengths longer than 650 nm. The reflectivity spectrum continuously moved downward, and the specimen color became darker and thicker with increasing Mn content. The CIELAB color change with respect to standard white was also dependent on the amount of Mn added: TRIANGLE L^{*} (D65) negatively increased and TRIANGLE E _{ab} ^{*} (D65) positively increased with increasing Mn content, probably due to Mn substitution to Al and/or the mixing effect of black Al2MnO4 as a second phase.
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Display and Optical Devices : Evaluation of Driving Properties by Cell-gap Difference of Single Particle-Microcapsule Type Electronic Paper
Jin Seok Song, Young Cho Kim
J Electr Electron Mater 2015;28(8):518-523.   Published online August 1, 2015
We fabricate a single particle-microcapsule type electronic paper using electrophoresis, which is different with a reported dual particle-microcapsule type and of which electro-optical researches are not reported. So we analyzed a basic properties, such as reflectivity, response time, and driving voltage. Our display panels having various cell-gaps of 30 ㎛, 34 ㎛, 38 ㎛, 42 ㎛, and 46 ㎛ are inspected. As a results, a driving voltage is defined to 10 V and desirable cell-gap is 30 ㎛ or 34 ㎛. Considering a mechanical strength, the optimum cell-gap is 34 ㎛ for the single particle type electronic paper.
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Analysis of Driving Characteristics by Putting Voltage of Charged Particle Type Display Device
Jin Sun Kim, Young Cho Kim
J Electr Electron Mater 2012;25(1):48-52.   Published online January 1, 2012
The charged particle type display device is a kind of the reflectivity type display and shows an image by absorption and reflection of external light source. The charged particle is important factor for driving of the display and quantity of charge per mass of the charged particle determines the driving voltage, contrast ratio, response time, etc. But it is easy for the charged particles to be damaged in the putting process of the display and the damages cause lumping phenomenon of the charged particles. Because the lumping phenomenon makes high driving voltage, low quality of optical properties, short life time, etc, so the charged particles must be filled by stable putting methods. In this paper, we filled the charged particles into the panels by electric fields to improve the electrical and optical characteristics of the display. Also, we analyzed the driving characteristics of the charged particles according to the applied putting voltages.
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Regular Paper : A Proposal of the Evaluation Method of Toner Particle Type Display
Cheol Woo Kim, Young Cho Kim
J Electr Electron Mater 2010;23(9):691-695.   Published online September 1, 2010
A measurement method of the particle-based reflective display is proposed, estimated, and compared with reported method. The reflectivity measurement by previous studies is simply obtained by integrating sphere, but it has a limitation for the estimation of real moving particles because its data include surface reflection and incomplete attachment on electrodes. To get the number of real moving particles, the area by attached particles on the electrodes is calculated at microscopic signals. The moving particles on subthreshold voltage are observed and this fluctuational variation of surface on subthreshold voltage gives a tip to understand the driving mechanism. By this measurement we ascertained the relationship of a particle layer and real driving particles, and the feasibility of observation and estimation for moving color particles, which were measured by the reflectivity and CIE (Commission Internationale de I`Eclairage) system of color specification at previous studies.
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Synthesis and Characterization of Al Film using N-methylpyrrolidine Alane
Moon Kyu Seo
J Electr Electron Mater 2009;22(7):549-554.   Published online July 1, 2009
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A Study on Optical Characteristics of Charged Toner Particle Type Display
Baek Hyun Kim, Sun Woo Park, Young Cho Kim
J Electr Electron Mater 2009;22(1):86-92.   Published online January 1, 2009
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