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"Temperature sensor"

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"Temperature sensor"

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Tutorial Status Report

Wearable temperature sensors are becoming increasingly important for continuous health monitoring, personalized healthcare, and biointegrated electronic systems. However, conventional temperature-sensing platforms often suffer from limited thermal sensitivity, insufficient mechanical compliance, and unstable performance under repeated deformation, making it difficult to detect subtle physiological temperature variations in real time. Here, this tutorial status report presents a fabrication strategy for highly sensitive wearable temperature sensors based on gold-doped crystalline silicon nanomembranes. Gold diffusion into crystalline silicon introduces deep-level impurity states that modulate the Fermi level and shift the freeze-out region toward the physiological temperature range, enabling an ultrahigh negative temperature coefficient of resistance. By integrating the gold-doped silicon nanomembrane with a polyimide-supported ultrathin platform, neutral mechanical plane design, and serpentine mesh interconnects, the resulting device can provide high thermal sensitivity, fast response, conformal skin attachment, and stable operation under mechanical deformation. This fabrication approach is expected to broaden the use of impurity-engineered silicon nanomembranes in next-generation wearable sensors, flexible bioelectronics, and multifunctional healthcare monitoring systems.
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Structural and Electrical Properties of (La0.7-xBixSr0.3)FeO₃ Ceramics for Application of Temperature Sensors
Se-ho Kang, Myung-gyu Lee, Sam-haeng Lee, Joo-seok Park, Sung-gap Lee
J Electr Electron Mater 2025;38(6):645-649.   Published online November 1, 2025
DOI: https://doi.org/10.4313/JEEM.2025.38.6.6
(La1-xBixSr0.3)FeO₃ ceramics exhibiting excellent magnetoresistance were synthesized via the conventional solid-state reaction method. The structural and electrical properties were investigated as a function of Bi3+ content to evaluate their potential application as temperature sensors. And the sintering temperature and time were 1,200℃ and 4 h, respectively. The structural and electrical properties were investigated as a function of Bi content. With increasing Bi substitution, a slight enhancement in both average grain size and relative sintered density was observed. In particular, the specimen with x = 0.3 exhibited an average grain size of approximately 0.82 μm. All samples demonstrated negative temperature coefficient of resistance (NTCR) behavior, and the electrical resistivity decreased with increasing Bi content. The resistivity of the (La0.4Bi0.3Sr0.3)FeO₃ composition was 4.68 mΩ-cm at 25°C. Additionally, the temperature coefficient of resistance (TCR) and the B25/75-value, which quantify the sensitivity of resistivity to temperature variations, were found to increase with Bi content. (La0.4Bi0.3Sr0.3)FeO₃ sample exhibited a TCR of 0.43%/°C and a B25/75-value of 1,096 K at room temperature. The electrical conduction mechanism of the (La1-xBixSr0.3)FeO₃ system was well described by the small polaron hopping model, wherein thermally activated charge carriers hop between localized Fe-O-Fe sites via electron-phonon interactions.
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A Flexible Self-Powered Temperature Sensor Based on Thermoelectric Composite Films
Da-eun Shin, Sua Kwon, Seo Yeon Bae, Jong Min Park, Cheol Min Kim, Kwi-il Park
J Electr Electron Mater 2025;38(4):442-447.   Published online July 1, 2025
DOI: https://doi.org/10.4313/JKEM.2025.38.4.14
The continuous and long-lasting monitoring of physiological signals induced from the human body is crucial for health monitoring, disease diagnosis, and treatment. In this study, we have reported the Seebeck effect-based flexible selfpowered temperature sensor which can convert the electric signals from lateral temperature difference. For demonstrating temperature sensor arrays, the p-type thermoelectric (TE) composite films were fabricated by dispersing the Bi0.5Sb1.5Te3 (BST) powders inside poly-vinylidene fluoride matrix and subsequently attached to the patterned electrode foils. The inorganic BST powders-embedded TE composite films with activated area of 0.5 × 1 cm² harvest a maximum voltage of 1.7 mV, a maximum current of 5.6 mA, and an output power of 2.6 nW from the temperature gradient (ΔT) of 20 K. Finally, the fabricated selfpowered temperature sensor array well detected the pattern images of external thermal source of ΔT = 20 K. This study manifests flexible temperature sensor array which paves the way for further advancements in this field.
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Structural and Electrical Properties of (1-x)La0.7Sr0.3MnO₃-xBaTiO₃ Ceramics for Temperature Sensors
Yong-seok Choi, Young-gon Kim, Sung-gap Lee
J Electr Electron Mater 2025;38(4):431-435.   Published online July 1, 2025
DOI: https://doi.org/10.4313/JKEM.2025.38.4.12
The composite specimens of (1-x)(La0.7Sr0.3)MnO₃-xBaTiO₃ (x = 0.05 ~ 0.3) were synthesized using the conventional solid-state reaction method, and the sintering temperature and time were 1,300℃ and 3 hours, respectively. As a result of observing the structural characteristics, the crystal structure of LSMO-BT solid solution was shown in which the rhombohedral LSMO phase and the tetragonal BT phase were separated and distributed, respectively. And fine grains having relatively small and uniformly distributed grains with sizes ranging from approximately 0.4 to 0.5 μm and pores within the specimens were observed. Notably, variations in the BT content did not significantly affect the grain size or porosity distribution, and a relative density of about 90% or more was shown. The resistivity, temperature coefficient of resistance (TCR), and B25/65-value of the 0.7LSMO-0.3BT specimen at room temperature showed the highest values of 1.94 Ω-cm, 0.292 %/℃, and 464 K, respectively. The resistivity behavior of the LSMO-BT composites matched well with the small polaron hopping conduction model.
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Study on the Fire Detection Characteristics of Si Based RGB Color Sensors
Jiwon Choi, Dongmin Seo, Haiyoung Jung
J Electr Electron Mater 2025;38(1):54-64.   Published online January 1, 2025
DOI: https://doi.org/10.4313/JKEM.2025.38.1.7
This paper presents a comparative analysis of the fire detection characteristics between conventional fire detector sensors and an Si-based color sensor. With the rapid industrial development in modern society, the concentration of urban populations and the expansion of building sizes have accelerated, leading to an increased frequency of large-scale fires. As a result, the importance of fire detection technologies has been emphasized. However, conventional detectors continue to experience issues such as false alarms and malfunctions. To address these challenges, a novel fire detection technology utilizing an Si-based color sensor, which is effective for fire detection, is proposed. To evaluate the fire detection performance of each sensor, a fire detection test apparatus was developed, and experiments were conducted separately under smoke and flame conditions to analyze the fire detection capabilities of the Si-based color sensor, temperature sensor, and flame detection sensor. The experimental results demonstrated that detection speed and sensor values varied depending on the type of combustible material. Specifically, in the smoke and flame tests, the Si-based color sensor detected fires 26.7 and 43.7 seconds faster than the temperature sensor, and 26.6 and 15.4 seconds faster than the flame detection sensor, respectively. Therefore, it was confirmed that the Si-based color sensor proposed in this study is an effective detection technology that is expected to provide improved performance compared to conventional fire detectors.
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Structural and Electrical Properties of Zn-Mn-O System Ceramics for the Application of Temperature Sensors
Kyeong Min Kim, Sung Gap Lee, Dong Jin Lee, Mi Ri Park, Min Soo Kwon
J Electr Electron Mater 2016;29(8):470-475.   Published online August 1, 2016
In this study, ZnxMn3-xO4 (x=0.95~1.20) specimens were prepared by using a conventional mixed oxide method. All specimens were sintered in air at 1,200℃ for 12 h and cooled at a rate of 2℃/min to 800℃, subsequently quenching to room temperature. We investigated the structural and electrical properties of ZnxMn3-xO4 specimens with variation of ZnO amount for the application of NTC thermistors. As results of X-ray diffraction patterns, all specimens showed the formation of a complete solid solution with tetragonal spinel phase. And, the second phase was observed by the solubility limit of Zn ions in x≥1.10 composition. The average grain size was increased from 2.72 μm to 4.18 μm with increasing the compositional ratio of Zn ion from x=0.95 to 1.20, respectively. Zn1.10 Mn1.90 O4 specimen showed the minimum electrical resistance of 57.5 kΩ at room temperature and activation energy of 0.392 eV.
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