UV-induced photosensing characteristics of SiC and GaN nanowires

Teker, Kasif; Ali, Yassir Abdullahi; Uzun, Ali

doi:10.1108/sr-09-2017-0199

Cited by 3 publications

(1 citation statement)

References 21 publications

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“…The wide band-gap and high thermal stability of SiC allow certain types of devices to operate indefinitely at junction temperatures of 300 °C or higher without measurable performance degradation. The potential markets for SiC sensors include the Radio Frequency (RF) MEMS [ 39 ], the pressure sensors used in the petroleum industry [ 40 ], the acceleration sensors in aircraft engines and motors [ 41 ], and the optical MEMS [ 42 ].…”

Section: Introductionmentioning

confidence: 99%

Modeling and Analysis of a SiC Microstructure-Based Capacitive Micro-Accelerometer

et al. 2021

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In this study, a comb-type capacitive accelerometer based on a silicon carbide (SiC) microstructure is presented and investigated by the finite element method (FEM). It has the advantages of low weight, small volume, and low cross-coupling. Compared with silicon(111) accelerometers with the same structure, it has a higher natural frequency. When the accelerometer vibrates, its resistive force consists of two main components: a viscous damping and an elastic damping force. It was found that viscous damping dominates at low frequency, and elastic damping dominates at high frequency. The second-order linear system of the accelerometer was analyzed in the time-frequency domain, and its dynamic characteristics were best when the gap between the capacitive plates was 1.23 μm. The range of this accelerometer was 0–100 g, which is 1.64 times that of a silicon(111) accelerometer with the same structure. In addition, the accelerometer could work normally at temperatures of up to 1200 °C, which is much higher than the working temperatures of silicon devices. Therefore, the proposed accelerometer showed superior performance compared to conventional silicon-based sensors for inertial measurements.

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Section: Introductionmentioning

confidence: 99%

Modeling and Analysis of a SiC Microstructure-Based Capacitive Micro-Accelerometer

et al. 2021

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Dielectrophoresis: Measurement technologies and auxiliary sensing applications

Hu,

Ji,

Chen

et al. 2024

Electrophoresis

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Dielectrophoresis (DEP), which arises from the interaction between dielectric particles and an aqueous solution in a nonuniform electric field, contributes to the manipulation of nano and microparticles in many fields, including colloid physics, analytical chemistry, molecular biology, clinical medicine, and pharmaceutics. The measurement of the DEP force could provide a more complete solution for verifying current classical DEP theories. This review reports various imaging, fluidic, optical, and mechanical approaches for measuring the DEP forces at different amplitudes and frequencies. The integration of DEP technology into sensors enables fast response, high sensitivity, precise discrimination, and label‐free detection of proteins, bacteria, colloidal particles, and cells. Therefore, this review provides an in‐depth overview of DEP‐based fabrication and measurements. Depending on the measurement requirements, DEP manipulation can be classified into assistance and integration approaches to improve sensor performance. To this end, an overview is dedicated to developing the concept of trapping‐on‐sensing, improving its structure and performance, and realizing fully DEP‐assisted lab‐on‐a‐chip systems.

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