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Volume 39(1); January 2026

Piezoelectric Speaker Technologies
Muhammad Sheeraz, Yeon Hak Jeong, Soon-jong Jeong, Chang Won Ahn
J Electr Electron Mater 2026;39(1):1-13.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.1
The growing demand for thinner, lighter, and more energy-efficient electronic systems has driven the development of acoustic technologies toward compact and flexible sound generation platforms. Despite significant progress, conventional electromagnetic speakers remain limited by bulky structures, energy losses, and poor compatibility with modern ultrathin devices. In this review, recent advancements in piezoelectric acoustic systems are presented, demonstrating a new generation of speakers capable of producing high-fidelity sound from ultra-slim, lightweight, and mechanically compliant designs. Through refined structural configurations and efficient electromechanical coupling, these piezoelectric exciters achieve strong acoustic output, fast response, and wide frequency operation while drastically reducing component thickness. These exciters also show their suitability for seamless integration into flexible displays, wearable devices, and automotive panels, offering enhanced spatial audio practicality and multifunctional operation, including demonstrative output and sensing. This advancement marks a step toward the convergence of acoustic, haptic, and interactive technologies, for the realization of sustainable and immersive humanmachine interfaces in future electronic and automotive systems.
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Fabrication and Analysis of Electrical and Mechanical Properties of CNF Composite Insulation Papers
Seohee Hwang, Chanyong Lee, Hangoo Cho, Jaehyeong Lee
J Electr Electron Mater 2026;39(1):14-18.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.2
Cellulose nanofiber (CNF) has attracted significant attention as a next-generation insulating material due to its ecofriendly nature and outstanding functionalities. However, conventional kraft insulation paper suffers from limited dielectric breakdown strength and long-term reliability under high-voltage conditions, highlighting the need for alternative materials. In this study, kraft pulp was combined with five types of CNFs (A, B, C: wood-based / D, E: non-wood-based) to fabricate composite insulation papers, and their electrical and mechanical properties were systematically evaluated. The results showed that CNF incorporation generally enhanced density and tensile strength, while certain types contributed to lowering dielectric constant and improving breakdown strength. Among the wood-based CNFs, type C exhibited the most balanced performance in terms of dielectric stability and mechanical reinforcement. Among the non-wood-based CNFs, type E demonstrated notable improvements in structural compactness and tensile strength, suggesting favorable reliability. Therefore, this study identifies CNF C among wood-based types and CNF E among non-wood-based types as the most promising candidates for insulation performance enhancement, suggesting their applicability as next-generation insulating materials for power equipment and ecofriendly electronic devices.
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Quench Behavior of Wires for Superconducting Fault Current Limiters at DC Faults
Hye-rim Kim, Bong-man Ahn, Byoung-sung Han
J Electr Electron Mater 2026;39(1):19-26.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.3
The quench behavior of wires for superconducting fault current limiters at DC faults was simulated, with a focus on the effect of capacitor discharge on the quench. The behavior was also expressed in mathematical forms to facilitate a better understanding of the simulation results and for rough analytical estimations of the wire length suitable for the circuit voltage and capacitance. The quench resistance development behavior for various wire lengths and circuit capacitances was simulated using the model developed in the previous work. The quench behavior was expressed in mathematical forms, reflecting the concept of heat balance. During the quench, the wire temperature increased more slowly for longer wires, but was found to increase in a similar pattern. The wire length estimated by the mathematical formula was close to the one obtained by the simulation, with an error range of a few %. The calculations will be used to estimate effectively the length of wires needed to build superconducting fault current limiters for applications in DC power systems.
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The Effect of Mask Thickness in The Silicon Etching by Using High Density Plasma
Jong-sik Kim, Jong-chang Woo, Gwan-ha Kim
J Electr Electron Mater 2026;39(1):27-33.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.4
This study investigates the effect of mask material and thickness on the silicon etching profile using a high-density plasma (HDP) etching system, aiming to reduce optical loss in silicon-based optical waveguides. As the mask thickness increased, the etching sidewall angle became steeper. An etching profile angle of 87° was obtained when tetraethyl orthosilicate (TEOS) was used as the mask material, while 80° was obtained for photoresist (PR). This is attributed to electron charging on the mask surface in the plasma. The charged mask modifies the distribution and strength of the electric field depending on its thickness, thereby affecting the trajectory of positive ions accelerated toward the substrate by the bias voltage. Furthermore, Plasma diagnostics using optical emission spectroscopy (OES) and surface composition analysis using field emission Auger electron spectroscopy (FE-AES) revealed that changes in the mask material also alter the reaction pathways and formation characteristics of active species and silicon by-products in the plasma. These results suggest that the mask material influences the overall plasma characteristics, including electron density and ion energy, and plays a critical role in the precise control of silicon etching profiles for high-performance optical device fabrication.
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Multilayer Ceramic Capacitors for AI Servers and Data Centers: Challenges, Reliability Issues, and Future Technology Directions
Jung Rag Yoon, Seok No Seo, Min-woo Ha, Moon-taek Cho
J Electr Electron Mater 2026;39(1):34-51.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.5
The rapid proliferation of artificial intelligence (AI) servers and high-performance computing systems has significantly elevated the technical and reliability requirements for multilayer ceramic capacitors (MLCCs). In such systems, MLCCs are critical passive components that must deliver high capacitance, fast transient response, and robust insulation performance under high temperature, voltage, and current density. This review examines the material, structural, and process innovations that underpin MLCC performance in AI applications. Key topics include the development of ultrathin dielectric layers (<0.5 μm), rare-earth doped BaTiO₃-based dielectrics with enhanced DC bias stability, and core-shell microstructures designed for temperature and field resilience. The paper also explores insulation degradation mechanisms―such as vacancydriven conduction and demixing―and advanced reliability assessment methodologies, including HALT, TSDC, and the tipping point framework. Comparisons with automotive-grade MLCCs highlight the unique requirements of AI systems, such as ultraminiaturization, high volumetric efficiency, and ppm-level field failure rates. Finally, the review discusses emerging trends in MLCC technology, including particle engineering, interface stabilization, and advanced lamination techniques, and provides insight into the future direction of capacitor development tailored to AI data center environments.
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A Study on the Explosion Characteristics of Off-Gases from Lithium-Ion Battery Thermal Runaway for EVs Marine Transport Safety
Jeong-hoon Park, In-chul Park
J Electr Electron Mater 2026;39(1):52-58.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.6
As electric vehicles (EVs) are rapidly adopted worldwide, large numbers are now transported by sea on dedicated car carriers. With this trend, concerns are increasing about fires and explosions caused by battery thermal runaway during marine transport, while existing SOC limits before loading remain largely empirical. This study experimentally investigates gas generation and explosion characteristics of EV lithium-ion cells under thermal runaway conditions representative of enclosed vehicle decks. We identify and quantify the main off-gas components and clarify the flammability behavior and explosion limits of key combustible species. The results provide basic data for assessing EV battery accidents at sea and support the development of safer ventilation and gas-management strategies for ships.
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Development of a Multi-Stress Characteristic Test Platform for Reliability Assessment of Dynamic Submarine Cables in Offshore Wind Farms
Seung-won Lee, Dong-eun Kim, Byung-bae Park, Hae Jong Kim, Ik-su Kwon
J Electr Electron Mater 2026;39(1):59-64.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.7
The increasing global demand for renewable energy has accelerated the deployment of offshore wind farms, thereby highlighting the need for advanced development and performance assessment techniques for dynamic submarine cables used in floating offshore wind systems. These cables are continuously subjected to combined thermal, electrical, and mechanical stresses, with mechanical loading playing a particularly dominant role. As a result, dynamic submarine cables exhibit degradation behaviors that differ significantly from those of conventional fixed submarine cables. This paper presents the design and implementation of a comprehensive evaluation system capable of applying combined thermal, electrical, and mechanical stresses to dynamic submarine cables. The system was validated using a 66 kV wet type submarine cable through commissioning tests and insulation performance measurements. Electrical stress of 72 kV, thermal stress exceeding 95°C, and mechanical stress corresponding to a bending radius of 20 times the cable diameter over 20 cycles were applied to verify system reliability. The subsequent insulation assessments quantitatively confirmed performance variations induced by the combined stresses. The results demonstrate that the proposed platform is the first system capable of simultaneously applying thermal, electrical, and mechanical stresses to dynamic submarine cables, and its operational performance has been successfully validated. This platform enables realistic reliability evaluation of dynamic cables used in floating offshore wind farms and is expected to improve the overall operational reliability of offshore wind power systems.
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Experimental Analysis of the Effect of Oil Viscosity on the Breakdown Strength of Cable Insulation
Seung-won Lee, Ik-su Kwon, Byung-bae Park, Dong-eun Kim, Hae-jong Kim
J Electr Electron Mater 2026;39(1):65-69.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.8
Breakdown strength is an essential parameter for evaluating the electrical performance and degradation behavior of cable insulation and IEC 60243 also emphasizes its importance for detecting changes in insulation characteristics due to aging. However, the current IEC standards are mainly limited to specifying electrode configurations and test voltage conditions for breakdown tests, while the influence of insulating oil, is not clearly addressed. In this study, the breakdown strength of a 66 kV wet-type submarine cable was experimentally evaluated using insulating oils with different kinematic viscosities of 10, 100, 500, and 1,000 cSt in order to achieve reliable and reproducible breakdown measurements. The experimental results show that the measured breakdown strength decreases by up to approximately 20% depending on the oil viscosity. This indicates that the viscosity of the insulating oil has a significant influence on the measured breakdown strength during breakdown test. Therefore, it is necessary to perform breakdown strength measurements under identical test conditions, including the physical properties of the insulating oil, to ensure reliable comparison and accurate assessment of insulation performance and degradation characteristics.
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Evaluation of Performance and Output Characteristics of Half-Bridge Bare Die 4H-SiC MOSFETs Under Variations of Switching Frequency and Duty Cycle
Yujin Seok, Hyoung Woo Kim, Ho-jun Lee, Chang-seung Ha
J Electr Electron Mater 2026;39(1):70-78.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.9
Silicon carbide (SiC) MOSFETs provide superior performance compared to traditional silicon devices under hightemperature and high-power conditions, making them particularly valuable for power electronics applications requiring highfrequency switching and high-energy efficiency. As the electric vehicle (EV) market expands, these devices are commonly packaged into six-pack modules, which can show their different electrical characteristics between the bare-die device and the package due to packaging that improves heat dissipation and other properties. This study uses bare-die SiC MOSFETs to explore their intrinsic characteristics and evaluate their performance in a half-bridge configuration. A half-bridge circuit was constructed, and performance was assessed by varying driving frequencies (10 kHz and 50 kHz) and adjusting the duty cycle between 20% and 80%. Analysis revealed that, at a fixed switching frequency, the average output voltage and average output current are proportional to the duty cycle.
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Humidity monitoring of exhaled breath has emerged as a vital approach for noninvasive respiratory health assessment, underscoring the need for sensitive and reliable humidity sensors. Despite its high conductivity and hydrophilic functional groups, reduced graphene oxide (rGO) often undergoes irreversible moisture adsorption and gradual oxidation by residual water, resulting in sensitivity degradation and long-term instability during cycling. In this study, a montmorillonite/reduced graphene oxide (MMT/rGO) composite is developed as a room-temperature humidity-sensing material, exhibiting an optimized response of 115%, more than 14 times higher than that of pristine rGO. This superior performance originates from the synergistic interaction between the reversible MMT swelling and the conductive rGO network near the electrical percolation transition, which ensures excellent stability and repeatability under repeated humidity cycles. These findings suggest that the MMT/rGO composite provides a cost-effective and biocompatible platform for next-generation wearable humidity sensors capable of continuous respiratory monitoring.
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Investigation of PAN-based Nanofiber Air Filters for Effective Carbon Dioxide Adsorption
Haebin Park, Jungwoo Hong, Soyoung Moon, Taejoon Lee, Dongwon Kang, Kyungtaek Min
J Electr Electron Mater 2026;39(1):88-93.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.11
The continuous rise of atmospheric carbon dioxide (CO₂) emissions highlights the urgent need for sustainable air purification technologies. Current Direct Air Capture (DAC) filters often rely on toxic amines, which limit long-term stability and safe application. Here, we report a non-toxic PAN-based nanofiber air filter fabricated by electrospinning and urea-assisted carbonization. Structural analyses confirmed the introduction of nitrogen functionalities that enhanced CO₂ affinity, while SEM and FT-IR revealed graphitic carbon formation. In air-chamber tests, the optimized carbonized nanofiber reduced CO₂ concentration from 25,000 ppm to 2,000 ppm, a level generally regarded as acceptable for indoor environments, while simultaneously removing over 95% of PM10, PM2.5, and PM0.1 particulates. This dual functionality, combined with facile fabrication and material safety, demonstrates strong potential for PAN-derived carbon nanofiber membranes in DAC systems and eco-friendly air purification devices. These findings suggest a viable pathway toward scalable, sustainable air-filter technologies for carbon-neutral applications.
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Balanced Charge Distribution by the Interface Controls of P3HT: PC70BM/Overlay Active-layers in Organic Photovoltaics
Gyumin Kyung, Hoseung Kang, Soonho Hong, Sunyoung Sohn
J Electr Electron Mater 2026;39(1):94-102.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.12
Organic photovoltaics (OPVs) are attractive candidates for sustainable energy conversion due to their flexibility, lowcost processing, and compatibility with large-area fabrication. However, their efficiency is hindered by interfacial defects and vertical phase separation in the active layer, which induce charge imbalance and recombination losses. This work presents an interfacial engineering approach to overcome these limitations in P3HT:PC70BM-based OPVs. Two key strategies were employed: (i) reducing the post-deposition annealing time of the active layer to suppress PC70BM accumulation at the bottom electrode, and (ii) using a DCB:DCM mixed solvent system to regulate solvent evaporation, thereby promoting uniform film formation during PC70BM overlay deposition. Devices fabricated with these optimizations exhibited notable enhancements, achieving short-circuit current density up to 15.83 mA/cm2 and a 58.1% increase in power conversion efficiency compared to control devices. X-ray photoelectron spectroscopy confirmed reduced surface aggregation of PC70BM, while X-ray diffraction indicated improved P3HT crystallinity and molecular ordering. These results highlight the critical role of interfacial and morphological control in enhancing charge separation and transport, offering a practical route toward efficient, reproducible, and stable OPVs.
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3D-Printed Liquid Metal Electrodes for Deformable Electronic Circuit
Jong Jun Jung, Sang Yoon Park, Se Jin Choi, Yu Jin Ko, Haneol Lee
J Electr Electron Mater 2026;39(1):103-109.   Published online January 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.1.13
Flexible and wearable electronics, which require stable operation under mechanical deformation, are increasingly utilizing Eutectic Gallium-Indium (EGaIn) for their conductive components. This study presents a systematic approach to fabricating highly reliable, deformable electrodes via a direct-ink-writing (DIW) 3D printing process using EGaIn as the functional ink. We conducted a thorough optimization of key printing parameters, specifically the extrusion pressure and printing speed, to achieve stable and uniform conductive lines. Through this optimization, we successfully established an optimal process window, achieving a stable line width of approximately 130 μm at an extrusion pressure of 300 kPa and a printing speed of 16 mm/s. The fabricated flexible electrodes exhibited exceptional electromechanical stability, maintaining negligible resistance change (< 0.82%) both under severe bending (3 mm radius) and after 100 repetitive bending cycles. This work demonstrates that the 3D printing of EGaIn is a viable and effective method for creating robust, high-performance electrodes for the next generation of deformable and wearable electronic devices.
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