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Ultrasensitive Carbon Monoxide Gas Sensor at Room Temperature Using Fluorine-Graphdiyne

Kim My Tran, Junoh Shim, Hyung‐Kun Lee, Hyung‐Kun Lee, Sohyeon Seo, Surajit Haldar, Hyoyoung Lee, Hyoyoung Lee

2023ACS Applied Materials & Interfaces18 citationsDOI

Abstract

Currently, most carbon monoxide (CO) gas sensors work at high temperatures of over 150 °C. Developing CO gas sensors that operate at room temperature is challenging because of the sensitivity trade-offs. Here, we report an ultrasensitive CO gas sensor at room temperature using fluorine-graphdiyne (F-GDY) in which electrons are increased by light. The GDY films used as channels of field-effect transistors were prepared by using chemical vapor deposition and were characterized by using various spectroscopic techniques. With exposure to UV light, F-GDY showed a more efficient photodoping effect than hydrogen-graphdiyne (H-GDY), resulting in a larger negative shift in the charge neutral point (CNP) to form an n-type semiconductor and an increase in the Fermi level from -5.27 to -5.01 eV. Upon CO exposure, the negatively shifted CNP moved toward a positive shift, and the electrical current decreased, indicating electron transfer from photodoped GDYs to CO. Dynamic sensing experiments demonstrated that negatively charged F-GDY is remarkably sensitive to an electron-deficient CO gas, even with a low concentration of 200 parts per billion. This work provides a promising solution for enhancing the CO sensitivity at room temperature and expanding the application of GDYs in electronic devices.

Topics & Concepts

Materials scienceCarbon monoxideFluorineCarbon fibersChemical engineeringNanotechnologyOrganic chemistryComposite materialCatalysisChemistryMetallurgyEngineeringComposite numberGas Sensing Nanomaterials and SensorsSpectroscopy and Laser ApplicationsAnalytical Chemistry and Sensors
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