一种基于超宽带射频识别系统的室温甲烷无芯片传感器

Jian Liu, Baiping Li
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引用次数: 0

摘要

为了在室温下检测甲烷气体,本文设计了一种超宽带无线射频识别(UWB-RFID)无芯片甲烷传感器。所提出的传感器是一种由天线和纳米技术启用的传感器头装备的薄膜。天线为平面贴片,边缘为弧形,通过集总电路负载进行阻抗匹配;传感器头是指间指电极(IDE),由钯修饰的单壁碳纳米管(Pd-SWCNTs)负载。该传感器的性能通过分析和数值分析进行了验证,根据预先设定的场景,甲烷浓度在室温下从0ppm增加到100ppm。结果表明,在带隙调幅机制下对传感器进行几何化处理,可实现-9.32dB的识别灵敏度;相反,如果在带隙调频机制中几何化,则可实现略高-11.30dB的识别灵敏度。
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A palladium decorated signal walled carbon nanotube enabled chipless sensor for detecting methane at room temperature based on UWB-RFID system
In order to detect methane at room temperature, a chipless methane sensor in ultra-wideband radio frequency identification (UWB-RFID) is designed in the paper. The proposed sensor is a type of thin film equipped by an antenna and a nano-technique enabled sensor head. The antenna is a planar patch with arc typed edge loaded by lumped circuit for impedance matching; the sensor head is an electrode with interdigitated fingers (IDE) loaded by the palladium decorated single walled carbon nanotubes (Pd-SWCNTs). The performance of the proposed sensor is validated by the analytical and numerical analyses in terms of a predefined scenario where the concentration of methane is increased from 0ppm to 100ppm at room temperature. Results show that, if the sensor is geometrized in the mechanism of amplitude modulation of band-gap, the identifiable sensitivity can achieve -9.32dB; on the contrary, if it is geometrized in the mechanism of frequency modulation of band-gap, the identifiable sensitivity can achieve a little bit high by -11.30dB.
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