Abstract
Carbon nanotubes (CNTs)-based sensors have gained significant importance due to their tremendous electrical and physical attributes. CNT-based gas sensors have high sensitivity, stability, and fast response time compared to that of solid-state sensors. On exposure to a large variety of organic and inorganic compounds, the conductivity of CNT changes. This change in electrical conductivity is being used as a detection signal to detect different target molecules. Hydrogen-sulfide and benzene are hazardous gases that can cause serious health issues in humans. Therefore, it is mandatory to detect their presence in industrial and household environments. In this article, we simulated CNT-based benzene and hydrogen-sulfide sensor with a nanoscale semiconductor device simulator—Quantumwise Atomistix Toolkit (ATK). The change in the device density of states, electric current, and photocurrent in the presence of target molecules have been calculated. The change in photocurrent in the presence of target molecules has been proposed as a novel detection mechanism to improve the sensor selectivity and accuracy. This change in photocurrent as well as electric current in the presence of target molecules can be used simultaneously as detection signals. Our intension in the future is to physically fabricate this simulated device and use photocurrent as well as electric current as detection mechanisms.
Highlights
The detection of hazardous biochemicals and gases in industrial and household environments have been a great concern
A light emitting diode can be used as a light source to illuminate Carbon nanotubes (CNTs) and change in photocurrent as well as electric current in the presence of different target molecules can be measured
The purpose of the work presented in this article is to access the feasibility of CNT as a benzene and hydrogen-sulfide molecule detector and introduce a new gas detection mechanism
Summary
The detection of hazardous biochemicals and gases in industrial and household environments have been a great concern. Nanomaterials, especially one-dimensional nanomaterials like carbon nanotubes, nanoribbons and nanowires, are promising candidates to replace the conventional solid-sate sensors due to their exceptional physical and electrical attributes. These materials have great adsorption capabilities and are very suitable to adsorb and detect a wide range of gases [1]. Nanomaterials based sensors are very promising candidates for the replacement of the chromatography technique due to their small size and low cost [22] Benzene is another hazardous gas and the major sources of benzene are petroleum products, automobile exhaust, building materials, and industrial discharges [23]. All the simulations have been done in a nanoscale semiconductor device simulator—Quantumwise Atomistix Toolkit
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