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"sputtering"

e investigated the effects of post-annealing in vacuum, nitrogen, and hydrogen atmospheres on the structural, electrical, and optical properties of 600 nm thick Al-doped ZnO (ZnO:Al) thin films deposited by RF magnetron sputtering at room temperature. Post-annealing in hydrogen atmosphere at 400℃ for 1 hour showed the most significant improvement in electrical properties. Resistivity decreased from 9.11×10⁻³ to 1.4×10⁻³ Ω·cm, electron mobility increased from 4.11 to 18.23 cm²/V·s, and electron carrier concentration increased from 1.63×10²⁰ to 4.85×10²⁰ cm⁻³. In contrast, post-annealing in vacuum and nitrogen atmospheres resulted in degraded electrical properties due to oxygen and nitrogen chemisorption at grain boundaries. The enhancement in hydrogen-annealed films was attributed to the formation of additional oxygen vacancies and desorption of adsorbed oxygen species from grain boundaries. All films maintained excellent optical transparency of 80-90% in the visible range. The optical bandgap exhibited a blue-shift from 3.365 eV to 3.624 eV due to the Burstein-Moss effect induced by the increased electron carrier concentration. These results confirmed that hydrogen atmosphere post-annealing is the most effective method for enhancing the electrical conductivity of ZnO:Al thin films while maintaining high optical transparency.
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Evaluation of Physicochemical Properties of Y2O3 Thin Films Deposited by RF Sputtering After Thermal Annealing
Jong-chang Woo, Jong-sik Kim, Insu Kang, Gwan-ha Kim
J Electr Electron Mater 2025;38(6):638-644.   Published online November 1, 2025
DOI: https://doi.org/10.4313/JEEM.2025.38.6.5
In this study, Y₂O₃ thin films were deposited on Si(100) wafers using an RF sputtering system with a Y₂O₃ target. The Y₂O₃ thin film was confirmed to have a thickness of 227 nm/min and a uniformity of 1.34% at a substrate temperature of 400℃. All samples were annealed at 600, 800, and 1,000℃ for 1 hour in an O₂ gas atmosphere using the furnace. The analysis of the XRD patterns revealed that the peak intensity increased with annealing up to 800℃, but decreased when the annealing temperature was raised to 1,000℃. The XPS analysis confirmed the onset of crystallization at 800℃, in agreement with the trends observed in the XRD results. According to the AFM results, the surface became slightly smoother after heat treatment, as indicated by a reduced RMS roughness of approximately 1.792 nm.
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Analysis of Cl₂/Ar Plasma Etching Characteristics for RF-Sputtered MoS₂ Films
Jong-chang Woo, Doo-seung Um, Gwan-ha Kim
J Electr Electron Mater 2025;38(5):560-566.   Published online September 1, 2025
DOI: https://doi.org/10.4313/JEEM.2025.38.5.12
Molybdenum disulfide (MoS₂) is a promising 2D semiconductor material for low-power electronics due to its excellent electrical properties and compatibility with conventional processes. In this study, MoS₂ thin films deposited by RF sputtering were etched using Cl₂/Ar plasma in an ICP system. The effects of Cl₂ gas ratio, RF power, and process pressure on etch rate and MoS₂/SiO₂ selectivity were investigated. Optimal results were obtained at 25% Cl₂, achieving ~38 nm/min etch rate and selectivity of 3.0. Increased source power improved both etch rate and selectivity, while higher bias power enhanced etching but reduced selectivity due to stronger ion bombardment. XPS analysis confirmed Mo-Cl and S-Cl bond formation after etching, indicating chemical reactions and some by-product residue. These results provide insights into optimized plasma etching of sputtered MoS₂ films for advanced 2D device fabrication
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Influence of Al Content on the Resonant Characteristics of Al-Mo Thin Film-Based SAW Devices
Jae-cheol Park
J Electr Electron Mater 2025;38(1):65-71.   Published online January 1, 2025
DOI: https://doi.org/10.4313/JKEM.2025.38.1.8
Al-Mo thin films were fabricated using combinatorial sputtering system to realize highly sensitive surface acoustic wave (SAW) devices. The Al-Mo sample library was grown with various chemical compositions and electrical resistivities, which provided important information for selecting the most suitable materials for SAW devices. As the SAWs generated from piezoelectric materials are significantly affected by the resistivity and density of the interdigital transducer (IDT) electrodes, three types of Al-Mo thin films with different Al contents were fabricated. The thickness of the Al-Mo thin film used in the SAW-IDT electrode was fixed at 150 nm. As the Al content of the Al-Mo thin film decreased from 81.2 to 30.3 at%, the resistivity decreased slightly from 5.43±0.15 to 4.87±0.1×10-5 Ω-cm, whereas the calculated density increased significantly from 4.1 to 7.9 g/㎤. The SAW device composed of Al-Mo IDT electrodes resonated at 143 MHz without frequency shifts; however, the selectivity of the resonant frequency and insertion loss deteriorated as the Al content decreased. This suggest that the resonant characteristics of the SAW devices fabricated with Al-Mo thin films were more strongly influenced by the material density rather than the electrical properties of the IDT electrodes.
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Impact of Hydrogen-Doped Indium Oxide Films on the Performance of Silicon Heterojunction Solar Cells
Hyeong Gi Park, Jaehyeong Lee, Junsin Yi
J Electr Electron Mater 2024;37(6):582-589.   Published online November 1, 2024
DOI: https://doi.org/10.4313/JKEM.2024.37.6.2
We investigated the potential of IO:H thin films and hydrogen doping to improve current density and fill factor for enhancing the performance of silicon heterojunction solar cells. We revealed that a transmittance of 86.7% and work function of 5.4 eV could be achieved by injecting 3 sccm of hydrogen gas. The lattice constant of 1.037 nm at the AB site indicates an anion antibonding tendency, and the work function increases as the Fermi level shifts to the valence band. Based on these findings, we fabricated a silicon heterojunction solar cell and achieved an efficiency of 18.53%, while computer simulation confirmed a conversion efficiency of 24.65%, an open-circuit voltage of 724 mV, and a fill factor of 82.72% at a current density of 41.15 mA/㎠.
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Effect on the Thermal Treatment for Improving Efficiency in Silicon Heterojunction Solar Cells
Hyeong Gi Park, Junsin Yi
J Electr Electron Mater 2024;37(4):439-444.   Published online July 1, 2024
DOI: https://doi.org/10.4313/JKEM.2024.37.4.12
This study investigates the post-thermal treatment effects on the efficiency of silicon heterojunction solar cells, specifically examining the influence of annealing on p-type microcrystalline silicon oxide and ITO thin films. By assessing changes in carrier concentration, mobility, resistivity, transmittance, and optical bandgap, we identified conditions that optimize these properties. Results reveal that appropriate annealing significantly enhances the fill factor and current density, leading to a notable improvement in overall solar cell efficiency. This research advances our understanding of thermal processing in siliconbased photovoltaics and provides valuable insights into the optimization of production techniques to maximize the performance of solar cells.
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Effects of Film Thickness and Post-Annealing Temperature on Properties of the High-Quality ITO Thin Films with RF Sputtering Without Oxygen
Jiha Seong, Hyungmin Kim, Seongmin Shin, Kyunghwan Kim, Jeongsoo Hong
J Electr Electron Mater 2024;37(3):253-260.   Published online May 1, 2024
DOI: https://doi.org/10.4313/JKEM.2024.37.3.3
In this study, ITO thin films were fabricated on a glass substrate at different thicknesses without introducing oxygen using RF sputtering system. The structural, electrical, and optical properties were evaluated at various thicknesses ranging from 50 to 300 mm. As the thickness of deposited ITO thin film become thicker from 50 to 100 mm, carrier concentration, mobility, and band gap energy also increased while the resistivity and transmittance decreased in the visible light region. When the film thickness increased from 100 to 300 mm, the carrier concentration, mobility, and band gap energy decreased while the resistivity and transmittance increased. The optimum electrical properties were obtained for the ITO film 100 nm. After optimizing the thickness, the ITO thin films were post-annealed at different temperatures ranging from 100 to 300℃. As the annealing temperature increased, the ITO crystal phase became clearer and the grain size also increased. In particular, the ITO thin film annealed at 300℃ indicated high carrier concentration (4.32 × 1021 cm-3), mobility (9.01 cm2/V·s) and low resistivity (6.22 × 10-4 Ω·cm). This means that the optimal post-annealing temperature is 300℃ and this ITO thin film is suitable for use in solar cells and display application.
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Changes in Structural, Electrical, and Optical Properties Depending on the Thickness of AZO Thin Films Deposited with FTS
Haechan Kim, Hyungmin Kim, Seongmin Shin, Kyunghwan Kim, Jeongsoo Hong
J Electr Electron Mater 2024;37(2):169-174.   Published online March 1, 2024
DOI: https://doi.org/10.4313/JKEM.2024.37.2.7
In this study, the structural, electrical, and optical properties of AZO films of various thicknesses are compared. The AZO films were deposited on a glass substrate by FTS (Facing-Target-Sputtering) This research was conducted to find the optimal thickness for Transparent Conductive Oxide (TCO). AZO has suitable properties for TCO such as low resistivity, and high transmittance. Thin films of all thicknesses showed a transmittance of over 80% in the visible light region and electrical properties improved as thickness increased. It was confirmed that the film of 300 nm thick had the best performance due to its low resistivity, and uniform surface. This research is expected to help find optimal conditions in various fields where TCO is used, such as solar cells, displays, and sensors in the future.
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Characteristics of Carbon-Doped Mo Thin Films for the Application in Organic Thin Film Transistor
Dong Hyun Kim, Yong Seob Park
J Electr Electron Mater 2023;36(6):588-593.   Published online November 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.6.8
The advantage of OTFT technology is that large-area circuits can be manufactured on flexible substrates using a lowcost solution process such as inkjet printing. Compared to silicon-based inorganic semiconductor processes, the process temperature is lower and the process time is shorter, so it can be widely applied to fields that do not require high electron mobility. Materials that have utility as electrode materials include carbon that can be solution-processed, transparent carbon thin films, and metallic nanoparticles, etc. are being studied. Recently, a technology has been developed to facilitate charge injection by coating the surface of the Al electrode with solution-processable titanium oxide (TiOx), which can greatly improve the performance of OTFT. In order to commercialize OTFT technology, an appropriate method is to use a complementary circuit with excellent reliability and stability. For this, insulators and channel semiconductors using organic materials must have stability in the air. In this study, carbon-doped Mo (MoC) thin films were fabricated with different graphite target power densities via unbalanced magnetron sputtering (UBM). The influence of graphite target power density on the structural, surface area, physical, and electrical properties of MoC films was investigated. MoC thin films deposited by the unbalanced magnetron sputtering method exhibited a smooth and uniform surface. However, as the graphite target power density increased, the rms surface roughness of the MoC film increased, and the hardness and elastic modulus of the MoC thin film increased. Additionally, as the graphite target power density increased, the resistivity value of the MoC film increased. In the performance of an organic thin film transistor using a MoC gate electrode, the carrier mobility, threshold voltage, and drain current on/off ratio (Ion/Ioff) showed 0.15 cm2/V·s, -5.6 V, and 7.5×104, respectively.
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Advanced Tellurium-Based Threshold Switching Devices for High-Density Memory Arrays
Seunghwan Kim, Changhwan Kim, Namwook Hur, Joonki Suh
J Electr Electron Mater 2023;36(6):547-555.   Published online November 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.6.2
High-density crossbar arrays based on storage class memory (SCM) are ideally suited to handle an exponential increase in data storage and processing as a central hardware unit in the era of AI-based technologies. To achieve this, selector devices are required to be co-integrated with SCM to address the sneak-path current issue that indispensably arises in such crossbar-type architecture. In this perspective, we first summarize the current state of tellurium-based threshold-switching devices and recent advances in the material, processing, and device aspects. We thoroughly review the physicochemical properties of elemental tellurium (Te) and representative binary tellurides, their tailored deposition techniques, and operating mechanisms when implemented in two-terminal threshold switching devices. Lastly, we discuss the promising research direction of Te-based selectors and possible issues that need to be considered in advance.
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The Effect of Sputtering Power on Amorphous Ga2O3 Deposited by RF Sputtering System
Hyungmin Kim, Sangbin Park, Kyunghwan Kim, Jeongsoo Hong
J Electr Electron Mater 2023;36(5):488-493.   Published online September 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.5.8
The effect of sputtering power on the amorphous Ga2O3 thin film deposited using the radio frequency sputtering system was evaluated. Amorphous Ga2O3 is cheaper and more efficiently fabricated than crystalline Ga2O3, and is studied in various fields such as RRAM, photodetector, and flexible devices. In this study, amorphous Ga2O3 was deposited by radio frequency sputtering system and represented a transmittance of over 80% in the visible light region and a homogeneous and dense surface. The optical band gap energy decreased as the sputtering power increased owing to the quantum size effect. Thus, the specific band gap of amorphous Ga2O3 can be obtained by adjusting the sputtering power, it indicates amorphous Ga2O3 can be used in various fields.
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Sputtering Technology and Prospect for Transparent Conductive Thin Film
Sangmo Kim, Kyung Hwan Kim
J Electr Electron Mater 2023;36(2):109-124.   Published online March 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.2.2
For decades, sputtering as a physical vapor deposition (PVD) method has been a widely used technique for film coating processes. The sputtering enables oxides, metals, alloys, nitrides, etc to be deposited on a wide variety of substrates from silicon wafers to polymer substrates. Meanwhile, transparent conductive oxides (TCOs) have played important roles as electrodes in electrical applications such as displays, sensors, solar cells, and thin-film transistors. TCO films fabricated through a sputtering process have a higher quality leading to an improved device performance than other films prepared with other methods. In this review, we discuss the mechanism of sputtering deposition and detail the TCO materials. Related technologies (processing conditions, materials, and applications) are introduced for electrical applications.
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Post-annealing Effect of NiO Thin Film Grown by RF Sputtering System on 4H-SiC Substrate
Soo-young Moon, Min-yeong Kim, Dong-wook Byun, Geon-hee Lee, Sang-mo Koo
J Electr Electron Mater 2023;36(2):170-174.   Published online March 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.2.10
Nickel oxide is a nonstoichiometric transparent conductive oxide with p-type conductivity, a wide-band energy gap of 3.4~4.0 eV, and excellent chemical stability, making it a very important candidate as a material for bipolar devices.P-type conductivity in Transparent Conductive Oxides (TCO) is controlled by the oxygen vacancy concentration. During the TCO film deposition process, additional oxygen diffusing into the NiO structure causes the formation of Ni 3p ions and Ni vacancies. This eventually affects the hole concentration of the p-type oxide thin film. In this work, the surface morphology and the electrical characteristics were confirmed in accordance with the annealing atmosphere of the nickel oxide thin film.
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Characteristics of VOx Thin Films Fabricated by Sputtering as Buffer Layer in Inverted Organic Solar Cell
Seong-soo Yang, Yong Seob Park
J Electr Electron Mater 2023;36(1):36-41.   Published online January 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.1.6
We investigated the properties of vanadium oxide (VOx) buffer layers deposited by a dual RF magnetron sputtering method under various target powers for inverted organic solar cells (IOSCs). Sputter fabricatged VOx thin films exhibited higher crystallinity with the increase of target power, resulting in a uniform and large grain size. The electrical properties of VOx films are improved with the increase of target power because of the increase of V content. In the results, the performance of IOSCs critically depended on the target power during the film growth because the crystalllinity of the VOx film affects the carrier mobility of the VOx film.
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Study of Pd Target Power Effects on Physical Characteristics of Pd-Doped Carbon Thin Films Using Dual Magnetron Sputtering Method
Young-chul Choi, Yong Seob Park
J Electr Electron Mater 2022;35(5):488-493.   Published online September 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.5.10
Generally, diamond-like carbon films (a-C:H, DLC) have been shown to have a low coefficient of friction, a high hardness and a low wear rate. Pd-doped C thin film was fabricated using a dual magnetron sputtering with two targets of graphite and palladium. Graphite target RF power was fixed and palladium target RF power was varied. The structural, physical, and surface properties of the deposited thin film were investigated, and the correlation among these properties was examined. The doping ratio of Pd increased as the RF power increased, and the surface roughness of the thin film decreased somewhat as the RF power increased. In addition, the hardness value of the thin film increased, and the adhesive strength was improved. It was confirmed that the value of the contact angle indicating the surface energy increases as the RF power increases. It was concluded that the increase in RF power contributed to the improvement of the physical properties of Pd-doped C thin film.
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Effect of Working Pressure Conditions during Sputtering on the Electrical Performance in Te Thin-Film Transistors
Kyu Ri Lee, Hyun-suk Kim
J Electr Electron Mater 2022;35(2):190-193.   Published online March 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.2.13
In this work, the effect of sputtering working pressure for the tellurium film and its thin-film transistor was investigated. The transfer characteristics of tellurium thin-film transistors were improved by increasing the working pressure during sputtering process. As increasing working pressure, physical and optical properties of Te films such as crystallinity, transmittance, and surface roughness were improved. Therefore, the improved transfer characteristics of Te thin-film transistors may originate from both improved interface properties between the silicon oxide gate dielectric layer and the tellurium active layer with an improved quality of Te film. In conclusion, the control of working pressure during sputtering would be important for obtaining highperformance tellurium-based thin film transistor.
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Effect of Structure Change in Second-Generation Superconducting Wire Stabilization Layer on Resistivity Characteristics
Sang-jae Ban, Ho-ik Du, Hyun-gi Jeong, Seung-gyu Doo, Sung-chae Yang
J Electr Electron Mater 2022;35(2):172-177.   Published online March 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.2.10
The quench voltage of the second-generation superconducting wire is affected by the resistivity characteristics of the stabilization layer. The specific resistance of the stabilization layer can be changed by the deposition process using RF magnetron sputtering. In this paper, a thin film made of a homogeneous material (Ag) and a dissimilar material (Cu) was deposited on the stabilization layer of the second-generation superconducting wire through RF magnetron sputtering. We found that the specific resistance was reduced by increasing the thickness of the stabilization layer. The reduction in the resistivity of the stabilization layer led to a decrease in the quench voltage of the second-generation superconducting wire. We suggest that various characteristic changes of the second-generation superconducting wire can be expected through the successful change in the resistivity of the stabilization layer of the proposed deposition process.
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A Study on the Electrical Characteristics of Ge2Sb2Te5/Ti/W-Ge8Sb2Te11 Structure for Multi-Level Phase Change Memory
Woo-young Oh, Hyun-yong Lee
J Electr Electron Mater 2022;35(1):44-49.   Published online January 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.1.7
In this paper, we investigated current (I)- and voltage (V)-sweeping properties in a double-stack structure, Ge2Sb2Te5/Ti/W-doped Ge8Sb2Te11, a candidate medium for applications to multilevel phase-change memory. 200-nm-thick Ge2Sb2Te5 and W-doped Ge8Sb2Te11 films were deposited on p-type Si(100) substrate using magnetron sputtering system, and the sheet resistance was measured using 4 point-probe method. The sheet resistance of amorphous-phase W-doped Ge8Sb2Te11 film was about 1 order larger than that of Ge2Sb2Te5 film. The I- and V-sweeping properties were measured using sourcemeter, pulse generator, and digital multimeter. The speed of amorphous-to-multilevel crystallization was evaluated from a graph of resistance vs. pulse duration (t) at a fixed applied voltage (12 V). All the double-stack cells exhibited a two-step phase change process with the multilevel memory states of high-middle-low resistance (HR-MR-LR). In particular, the stable MR state is required to guarantee the reliability of the multilevel phase-change memory. For the Ge2Sb2Te5 (150 nm)/Ti (20 nm)/WGe8Sb2Te11 (50 nm), the phase transformations of HR→MR and MR→LR were observed at t<30ns and t<65ns, respectively. We believe that a high speed and stable multilevel phase-change memory can be optimized by the double-stack structure of proper Ge-Sb-Te films separated by a barrier metal (Ti).
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Structural, Electrical, and Optical Properties of AGZO Thin Films Using RF Magnetron Sputtering System Under Ar Flow Rates
Seok-hyeon Jang, Deok Kyu Kim
J Electr Electron Mater 2022;35(1):32-36.   Published online January 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.1.5
AGZO thin films were deposited on glass substrates using RF magnetron sputtering system under Ar flow rates, and their structural, electrical, and optical properties were analyzed systematically. As a result of the XRD pattern, the peak of the (002) (2θ≈33.7˚) orientation was observed, and it was found to have a hexagonal wurtzite structure. The sheet resistance of Ar 5 sccm was 3.073×102 Ω/sq and showed the best electrical properties because of the improvement of mobility due to the increase of the grain size and the variation of RMS roughness. In addition, the average transmittance was more than 90% for all samples, which demonstrated good optical properties. It is expected that the TCO characteristics can be improved by controlling Ar flow rates, and this will increase the efficiency of photoelectronic devices such as OLED and solar cells.
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In the case of ZnO:Al thin films, it is the best material that can replace ITO that is mainly used as a transparent electrode in electronic devices such as solar cells and flat-panel displays. In this study, ZnO:Al films were fabricated by using the RF dual magnetron sputtering method at various substrate temperatures. As the substrate temperature increased, the crystallinity of the ZnO:Al thin films was improved, and the electrical conductivity and electrical properties of the thin film improved owing to the increase in grain size. In addition, the surface roughness of the ZnO:Al thin films increased due to changes in the surface and density of the thin films. Moreover, the substrate temperature increased the density of thin films and improved their transmittance. To be applied to solar cells and other several electronic devices in the future, the hardness and adhesion properties of the thin film improve as the substrate temperature increases.
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Using facing target magnetron sputtering (FTMS) with a graphite target source, carbon nitride thin films were deposited on silicon and glass substrates at different substrate temperatures to confirm the tribological, electrical, and structural properties of thin films. The substrate temperatures were room temperature, 150℃, and 300℃. The tribology and electrical properties of the carbon nitride thin films were measured as the substrate temperature increased, and a study on the relation between these results and structural properties was conducted. The results show that the increase in the substrate temperature during the fabrication of the carbon nitride thin films increased the hardness and elastic modulus values, the critical load value was increased, and the residual stress value was reduced. Moreover, the increase in the substrate temperature during thin-film deposition was attributed to the improvement in the electrical properties of carbon nitride thin film.
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A Study on the Surface Properties of Polymer Insulators for Improving Electrical Insulation Performance
Yong Seob Park, Jae Sung Bae, Byungyou Hong, Jae Hyeong Lee
J Electr Electron Mater 2021;34(1):63-67.   Published online January 1, 2021
DOI: https://doi.org/10.4313/JKEM.2021.34.1.11
In this paper, we investigated the surface properties of polymer insulators to improve electrical insulation performance. First, after washing the polymer insulator in various ways, its contact angle was increased, thereby improving the hydrophobic properties and electrical insulation properties. In addition, TiO2 thin films, which have been used as a photocatalytic material and have been applied to the polymer insulator surface of to enhance the surface and electrical insulating properties. For the sputtering method, the contact angle after coating the TiO2 thin film increased with increasing RF power, but it was lower compared to that before coating, indicating that the hydrophobic properties of the surface were slightly deteriorated. Consequently, the electrical properties of the polymer-insulating material were maintained or improved after the TiO2 thin-film coating.
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Properties of ZnO:Ga Thin Films Deposited by RF Magnetron Sputtering with Ar Gas Flows
Deok Kyu Kim
J Electr Electron Mater 2020;33(6):450-453.   Published online November 1, 2020
DOI: https://doi.org/10.4313/JKEM.2021.33.6.4
In this study, ZnO:Ga thin films were fabricated on a glass substrate using various Ar flows by an RF magnetron sputter system at room temperature. The dependencies of Ar flow on different properties were investigated. An appropriate control over the Ar flow led to the formation of a high-quality thin film. The ZnO:Ga films were formed as a hexagonal wurtzite structure with high (002) preferential orientation. The films exhibited a typical columnar microstructure and a smooth top face. The average transmittance was 85~89% within the visible area. By decreasing the Ar flow, the sheet resistance was decreased due to an increase in the grain size and a decrease in the root mean square roughness. The lowest sheet resistance of 86 Ω/□ was obtained at room temperature for the 40 sccm Ar flow.
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The Study of Electrical and Structural Performance of Aluminum Thin Film Deposited by Sputtering Method
Doyoung Kim
J Electr Electron Mater 2020;33(2):114-117.   Published online March 1, 2020
DOI: https://doi.org/10.4313/JKEM.2021.33.2.7
In this study, we performed the deposition of Al thin film using a DC magnetron sputtering method. To evaluate electrical and structural properties, the growth conditions were changed in terms of two functions, namely, sputtering power ranging from 41.6 to 216 W and film growth rate ranging from 5.35 to 26.39 nm/min. The growth rate and the microstructure were characterized by a scanning electron microscopy and X-ray diffraction analysis. The plane of crystalline growth showed that the preferential (111) direction and defects due to the grain boundary increased with DC power. The resistivity of the Al film over 50 nm showed a constant value by horizontal grain growth. Our results can be applicable for the preparation of nano-templates for anodic aluminum oxide.
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The Effect of Substrate Roughness on the Fabrication and Performance of All-Solid-State Thin-Film Lithium-Ion Battery
Jong Heon Kim, Cheng-fan Xiao, Kwangmo Go, Kyung Jin Lee, Hyun-suk Kim
J Electr Electron Mater 2019;32(6):437-443.   Published online November 1, 2019
All-solid-state thin-film lithium-ion batteries are important in the development of next-generation energy storage devices with high energy density. However, thin-film batteries have many challenges in their manufacturing procedure. This is because there are many factors, such as substrate selection, to consider when producing the thin film multilayer structure. In this study, we compare the fabrication and performance of all-solid-state thin-film lithium-ion batteries with a LiNi0.5Mn1.5O4 cathode/LiPON solid electrolyte/ Li4Ti5O12 anode structure using stainless steel and Si substrates with different surface roughness. We demonstrate that the smoother the surface of the substrate, the thinner the thickness of the all-solid-state thin-film lithium-ion battery that can be made, and as a result, the corresponding electrochemical characteristics can be improved.
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Characteristics of Cu-Doped Ge8Sb2Te11 Thin Films for PRAM
Yeong-mi Kim, Heon Kong, Byung-cheul Kim, Hyun-yong Lee
J Electr Electron Mater 2019;32(5):376-381.   Published online September 1, 2019
In this work, we evaluated the structural, electrical and optical properties of Ge8Sb2Te11 and Cu-doped Ge8Sb2Te11 thin films prepared by rf-magnetron reactive sputtering. The 200-nm-thick deposited films were annealed in a range of 100~400℃ using a furnace in an N2 atmosphere. The amorphous-to-crystalline phase changes of the thin films were investigated by X-ray diffraction (XRD), UV-Vis-IR spectrophotometry, a 4-point probe, and a source meter. A one-step phase transformation from amorphous to face-centered-cubic (fcc) and an increase of the crystallization temperature (Tc) was observed in the Cu-doped film, which indicates an enhanced thermal stability in the amorphous state. The difference in the optical energy band gap (Eop) between the amorphous and crystalline phases was relatively large, approximately 0.38~0.41 eV, which is beneficial for reducing the noise in the memory devices. The sheet resistance(Rs) of the amorphous phase in the Cu-doped film was about 1.5 orders larger than that in undoped film. A large Rs in the amorphous phase will reduce the programming current in the memory device. An increase of threshold voltage (Vth) was seen in the Cu-doped film, which implied a high thermal efficiency. This suggests that the Cu-doped Ge8Sb2Te11 thin film is a good candidate for PRAM.
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Effect of Deposition Temperature on the Optical Properties of La2MoO6:Dy3+,Eu3+ Phosphor Thin Films
Shinho Cho
J Electr Electron Mater 2019;32(5):387-392.   Published online September 1, 2019
Dy3+ and Eu3+-co-doped La2MoO6 phosphor thin films were deposited on sapphire substrates by radio-frequency magnetron sputtering at various growth temperatures. The phosphor thin films were characterized using X-ray diffraction (XRD), scanning electron microscopy, ultraviolet-visible spectroscopy, and fluorescence spectrometry. The optical transmittance, absorbance, bandgap, and photoluminescence intensity of the La2MoO6 phosphor thin films were found to depend on the growth temperature. The XRD patterns demonstrated that all the phosphor thin films, irrespective of growth temperatures, had a tetragonal structure. The phosphor thin film deposited at a growth temperature of 100℃ indicated an average transmittance of 85.3% in the 400~1,100 nm wavelength range and a bandgap energy of 4.31 eV. As the growth temperature increased, the bandgap energy gradually decreased. The emission spectra under ultraviolet excitation at 268 nm exhibited an intense red emission line at 616 nm and a weak emission line at 699 nm due to the 5D07F2 and 5D07F4 transitions of the Eu3+ ions, respectively, and also featured a yellow emission band at 573 nm, resulting from the 4F9/26H13/2 transition of the Dy3+ ions. The results suggest that La2MoO6 phosphor thin films can be used as light-emitting layers for inorganic thin film electroluminescent devices.
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Investigation on Electrical Property of Amorphous Oxide SiZnSnO Semiconducting Thin Films
Jae Min Byun, Sang Yeol Lee
J Electr Electron Mater 2019;32(4):272-275.   Published online July 1, 2019
We investigated the electrical characteristics of amorphous silicon-zinc-tin-oxide (a-SZTO) thin films deposited by RF-magnetron sputtering at room temperature depending on the deposition time. We fabricated a thin film transistor (TFT) with a bottom gate structure and various channel thicknesses. With increasing channel thickness, the threshold voltage shifted negatively from -0.44 V to -2.18 V, the on current (Ion) and field effect mobility (μFE) increased because of increasing carrier concentration. The a-SZTO film was fabricated and analyzed in terms of the contact resistance and channel resistance. In this study, the transmission line method (TLM) was adopted and investigated. With increasing channel thickness, the contact resistance and sheet resistance both decreased.
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Effects of an a-C:H Anti-Reflective Coating on the Cell Efficiency of Dye-Sensitized Solar Cells (DSSCs)
Jae-sil Song, Nam-hoon Kim, Yong Seob Park
J Electr Electron Mater 2019;32(4):281-286.   Published online July 1, 2019
Raman spectra of a-C:H thin films deposited with an unbalanced magnetron sputtering system showed that the G peak shifted to a higher wavenumber as the target power density increased and ID/IG ratio increased from 0.902 to 1.012. Moreover, the transmittance of a-C:H films fabricated at 60 nm tended to decrease with increasing target power density; at 550 nm in the visible light region, the transmittance decreased from 69% to 58%. The rms surface roughness values of the a-C:H thin films decreased with increasing target power density, and varied from 1.11 nm to 0.71 nm. In order to achieve efficient light trapping, the light scattering at the rough interface must be enhanced. Consequently, the surface roughness of the thin film will decrease with the target power density. Further, the refractive index and reflectivity of the a-C:H thin films increased with increasing target power density; however, the Brewster angle decreased with the target power density. Hence, dye-sensitized solar cells using an a-C:H antireflective coating increased the CE, VOC, and JSC by approximately 8.6%, 5.5%, and 4.5%, respectively.
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TiN thin films were fabricated using an unbalanced magnetron sputtering (UBMS) system, and their structure and surface characteristics as well as their optical and tribological properties were evaluated. The hardness, elastic modulus, adhesive force, surface roughness, and transmittance of the Ti thin films fabricated using the UBMS system were 11.5 GPa, 103 GPa, 27.5 N, 2.45 nm and 20%, respectively. The TiN films prepared with various proportions of nitrogen as the reaction gas exhibited maximum values for the hardness, elastic modulus, critical load, RMS roughness and transmittance of approximately 19.2 GPa, 182 GPa, 27.3 N, 0.98 nm, and 85%, respectively. Moreover, the TiN thin film fabricated under the condition of 30 sccm nitrogen gas showed the optimal physical properties. In summary, the TiN thin films fabricated using the UBMS system exhibited excellent hardness, elastic modulus, adhesion, and smooth surface in addition to good hydrophilic properties.
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