Growth of defect-induced carbon nanotubes for low-temperature fruit monitoring sensor

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Abstract

Herein, a carbon nanotubes-based sensor has been grown for the purpose of ethylene detection. The prepared CNTs had a crystalline structure with a smooth surface of 11.0 nm in diameter and 10.0 µm in length. The low-intensity graphite peak (G-band) as compared to the peak of the defect (D-band) characterizes the defects in the CNTs. An MWNTs-gas sensor was fabricated for monitoring the ethylene gas. The highest response was recorded at a low operating temperature of 30◦ C. The sensor was also examined at 300 ppb up to 10 ppm and it showed a response of 2% up to 28%. The sensor response and recovery time constants were varied from 60 to 300 s, depending on the gas concentration. The results that were obtained for the synthetic ethylene gas were also compared with the real measurements for banana ripening. The results confirmed that the sensor is appropriate for the monitoring of fruit ripening.

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Shaalan, N. M., Saber, O., Ahmed, F., Aljaafari, A., & Kumar, S. (2021). Growth of defect-induced carbon nanotubes for low-temperature fruit monitoring sensor. Chemosensors, 9(6). https://doi.org/10.3390/chemosensors9060131

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