Electrospun Cu-doped In2O3 hollow nanofibers with enhanced H2S gas sensing performance

Zhang, Yu; Han, Shuai; Wang, Mingyuan; Liu, Siwei; Liu, Guiwu; Meng, Xiangchao; Xu, Ziwei; Wang, Mingsong; Qiao, Guanjun

doi:10.1007/s40145-021-0546-2

Cited by 90 publications

(27 citation statements)

References 62 publications

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“…After the sensor is exposed to the target gas (eqn (4) and (5)), 55 the H 2 S molecules will be adsorbed to the surface and react with adsorbed oxygen to generate SO 2 and H 2 O; meanwhile, trapped electrons are released to the conduction band of SnO 2 . This will lead to a decrease in the thickness of the electron depletion layer and a reduction in resistance.2H 2 S (gas) + 3O 2 − (ads) → 2SO 2 (gas) + 2H 2 O (gas) + 3e − H 2 S (gas) + 3O − (ads) → SO 2 (gas) + H 2 O (gas) + 3e − …”

Section: Resultsmentioning

confidence: 99%

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection

et al. 2022

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Section: Resultsmentioning

confidence: 99%

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection

et al. 2022

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“…The gas response goes hand in hand with the specific surface area and porosity of the material [48,49]. Therefore, researchers' research on topography is based on high specific surface area and porosity.…”

Section: Morphologymentioning

confidence: 99%

NiO-Based Gas Sensors for Ethanol Detection: Recent Progress

Zeng

2022

Journal of Sensors

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In this review, we summarized the state-of-the-art progress on the ethanol performance of NiO by means of morphology, doping, loading noble metal particles, and forming heterojunctions. We first introduced the effect of modulating NiO morphology on ethanol performance that has been reported in recent years. The morphology with large specific surface area and high porosity was considered to be the one that can bring high gas response. Then, we discussed the enhanced effect of the doping of metal cations and noble metal particle loading on the ethanol-sensitive properties of NiO. Doping ions increased the ground-state resistance and increased the oxygen defect concentration of NiO. The effects of noble metal particles on the performance of NiO included chemical sensitization and electronic sensitization. Finally, the related contents of NiO forming complexes with metal oxides and bimetallic oxides were discussed. In this section, the specific improvement mechanism was discussed first, and then, the related work of researchers in recent years was summarized. At the same time, we presented a reasonable outlook for NiO-based ethanol sensors, imagining future directions.

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“…Additionally, Ce 3+ would replace Ce 4+ , and oxygen vacancy would also produce to reach the balance of charge [49,50]. Hence, the proportion of O V was further increased, and the negative charge was released onto the conduction band, simultaneously increasing the carrier concentration [51][52][53].…”

Section: Gas Sensing Mechanismmentioning

confidence: 99%

Oxygen vacancy engineering on cerium oxide nanowires for room-temperature linalool detection in rice aging

Zhang

2022

J Adv Ceram

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It is a huge challenge for metal oxide semiconductor gas sensors to inspect volatile organic compounds (VOCs) at room temperature (RT). Herein, the effective utilization of cerium oxide (CeO2) nanowires for RT detection of VOCs was realized via regulating its surface chemical state. Oxygen vacancy engineering on CeO2 nanowires, synthesized via hydrothermal method, can be manipulated by annealing under various controlled atmospheres. The sample annealed under 5%H2+95%Ar condition exhibited outstanding RT sensing properties, displaying a high response of 16.7 towards 20 ppm linalool, a fast response and recovery time (16 and 121 s, respectively), and a low detection of limit of 0.54 ppm. The enhanced sensing performance could be ascribed for the synergistic effects of its nanowire morphology, the large specific surface area (83.95 m2/g), and the formation of extensive oxygen vacancy accompanied by an increase in Ce3+. Additionally, the practicability of the sensor was verified via two varieties of rice (Indica and Japonica rice) stored in various periods (1, 3, 5, 7, 15, and 30 d). The experimental results revealed that the sensor was able to distinguish Indica rice from Japonica rice. Accordingly, the as-developed sensor delivers a strategic material to develop high-performance RT electronic nose equipment for monitoring rice quality.

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Electrospun Cu-doped In2O3 hollow nanofibers with enhanced H2S gas sensing performance

Cited by 90 publications

References 62 publications

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection

NiO-Based Gas Sensors for Ethanol Detection: Recent Progress

Oxygen vacancy engineering on cerium oxide nanowires for room-temperature linalool detection in rice aging

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Electrospun Cu-doped In2O3 hollow nanofibers with enhanced H2S gas sensing performance

Cited by 90 publications

References 62 publications

Co,N-doped GQDs/SnO2 mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H2S gas detection

Co,N-doped GQDs/SnO2 mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H2S gas detection

NiO-Based Gas Sensors for Ethanol Detection: Recent Progress

Oxygen vacancy engineering on cerium oxide nanowires for room-temperature linalool detection in rice aging

Contact Info

Product

Resources

About

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection

Co,N-doped GQDs/SnO₂ mesoporous microspheres exhibit synergistically enhanced gas sensing properties for H₂S gas detection