Abstract
Possessing a large surface-to-volume ratio is significant to the sensitive gas detection of semiconductor nanostructures. Here, we propose a fast-response ammonia gas sensor based on porous nanostructured zinc oxide (ZnO) film, which is fabricated through physical vapor deposition and subsequent thermal annealing. In general, an extremely thin silver (Ag) layer (1, 3, 5 nm) and a 100 nm ZnO film are sequentially deposited on the SiO2/Si substrate by a magnetron sputtering method. The porous nanostructure of ZnO film is formed after thermal annealing contributed by the diffusion of Ag among ZnO crystal grains and the expansion of the ZnO film. Different thicknesses of the Ag layer help the formation of different sizes and quantities of hollows uniformly distributed in the ZnO film, which is demonstrated to hold superior gas sensing abilities than the compact ZnO film. The responses of the different porous ZnO films were also investigated in the ammonia concentration range of 10 to 300 ppm. Experimental results demonstrate that the ZnO/Ag(3 nm) sensor possesses a good electrical resistance variation of 85.74% after exposing the sample to 300 ppm ammonia gas for 310 s. Interestingly, a fast response of 61.18% in 60 s for 300 ppm ammonia gas has been achieved from the ZnO/Ag(5 nm) sensor, which costs only 6 s for the response increase to 10%. Therefore, this controllable, porous, nanostructured ZnO film maintaining a sensitive gas response, fabricated by the physical deposition approach, will be of great interest to the gas-sensing community.
Highlights
Liquid ammonia, widely used as a raw material for medicines, pesticides, organic chemical products, and refrigerants, is an important but dangerous chemical
zinc oxide (ZnO) film and ZnO/Ag nanostructured films were deposited on the substrates respectively at room temperature by the radio frequency (RF) magnetron sputtering system, and the ZnO layers were set to the same thickness of 100 nm
The porous nanostructures of ZnO/Ag nanostructured film were experimentally prepared through physical vapor deposition of silver and ZnO layers, followed by thermal annealing in air
Summary
Widely used as a raw material for medicines, pesticides, organic chemical products, and refrigerants, is an important but dangerous chemical. ZnO formed heterojunctions with other highly conductive materials like rGO [5], SWCNT [24], PPy [25], and PANI [26], helping to reduce the working temperature successfully In this present work, an ammonia gas sensor based on nanostructured ZnO film with uniformly distributed nano-hollows is successfully fabricated through physical preparation methods. Besides the improved sensitivity over the compact ZnO film, the fast response of the different porous ZnO films were compared and studied under the concentration range of 10 to 300 ppm at an operating temperature of 300 ◦ C. Our proposed physically deposited porous ZnO nanostructured film, which achieves a one-minute warning function, has potential as a mobile ammonia alarm due to its fast response, high stability, and feasibility of miniaturization
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