Low temperature and fast response hydrogen gas sensor with Pd coated SnO2 nanofiber rods

Wang, Feipeng; Hu, Kelin; Liu, Hongcheng; Wang, Kaizheng; Zhang, Jintao

doi:10.1016/j.ijhydene.2019.12.152

Cited by 90 publications

(26 citation statements)

References 44 publications

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“…Similar regions in calibration curve are reported in literature [33][34][35]. The comparison of SnO2 sensing performance to the recent literatures were depicted in Table 3 [36][37][38][39][40][41][42].…”

Section: Lpg Sensor Performancesupporting

confidence: 78%

Synthesis and Screen Printing of Dopant Free Nano-crystalline SnO2 (101) Thick Film for Gas Sensor Application

Garje¹,

Ovhal

Mishra³

et al. 2020

Adv. Mater. Lett.

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Section: Lpg Sensor Performancesupporting

confidence: 78%

Synthesis and Screen Printing of Dopant Free Nano-crystalline SnO2 (101) Thick Film for Gas Sensor Application

Garje¹,

Ovhal

Mishra³

et al. 2020

Adv. Mater. Lett.

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“…Furthermore, we note that testing sensor selectivity is particularly important for oxide-based sensors, because unlike Pd, they do not have inherent selectivity toward hydrogen gas. Therefore, oxide sensors usually employ a Pd coating/capping to improve the selectivity, as, for instance, shown for Pd-capped SnO 2 nanorods 84 and TiO 2 nanotubes. 85 Therefore, understanding the limiting factors of Pd–hydrogen interactions is equally important for this class of sensors.…”

Section: Hydrogen Sensor State-of-the-art With Respect To the Us Doe mentioning

confidence: 99%

High-Performance Nanostructured Palladium-Based Hydrogen Sensors—Current Limitations and Strategies for Their Mitigation

Nugroho²,

2020

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Hydrogen gas is rapidly approaching a global breakthrough as a carbon-free energy vector. In such a hydrogen economy, safety sensors for hydrogen leak detection will be an indispensable element along the entire value chain, from the site of hydrogen production to the point of consumption, due to the high flammability of hydrogen–air mixtures. To stimulate and guide the development of such sensors, industrial and governmental stakeholders have defined sets of strict performance targets, which are yet to be entirely fulfilled. In this Perspective, we summarize recent efforts and discuss research strategies for the development of hydrogen sensors that aim at meeting the set performance goals. In the first part, we describe the state-of-the-art for fast and selective hydrogen sensors at the research level, and we identify nanostructured Pd transducer materials as the common denominator in the best performing solutions. As a consequence, in the second part, we introduce the fundamentals of the Pd–hydrogen interaction to lay the foundation for a detailed discussion of key strategies and Pd-based material design rules necessary for the development of next generation high-performance nanostructured Pd-based hydrogen sensors that are on par with even the most stringent and challenging performance targets.

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“…Ubiquitous in various industries and settings, gas sensors are devices that allow for detection of gaseous molecules, which have applications ranging from manufacturing process control to environmental monitoring and emission control, and especially for fire safety (i.e., smoke alarms) in everyday life. Gas sensors are designed and optimized to have performance criteria for specific applications, such as, the ability to detect low concentrations of certain gas analytes in the ppb levels, [ 1–7 ] to have short response time, [ 8–11 ] and low power consumption (i.e., low operation temperature). [ 12,13 ] With the advancement in nanotechnology, this has consequently enabled significant improvements in the field of gas sensors, especially via development of novel sensing nanomaterials for enhancement of sensor performance.…”

Section: Introductionmentioning

confidence: 99%

1D Metal Oxide Semiconductor Materials for Chemiresistive Gas Sensors: A Review

Yang

Myung

Tran

2021

Adv Elect Materials

155

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While numerous types of gas sensors have been developed for various industries and applications such as the automotive industry, environmental monitoring, and personal safety, nanoscale chemiresistive gas sensors have gained significant research interest due to several advantages such as high sensitivity, low power consumption, and portability. An essential component of these gas sensors is the sensing material where metal oxide semiconductor (MOS) materials are the most prevalent sensing material. Since the adoption of nanoscale synthesis methods for sensing materials development, such as electrospinning and hydrothermal synthesis, many novel 1D MOS‐based nanostructured sensing materials have been demonstrated to enhance gas sensing performance. Overall, nanoengineering approaches and mechanisms for enhancement of gas sensing performance of 1D metal oxide‐based sensing materials are systematically discussed and categorized into several overarching strategies, such as tuning of materials dimension, morphology, and composition. Furthermore, integration of 1D sensing nanomaterials into sensor devices are discussed from the perspective of different chemiresistive sensor architectures and device fabrication methods. Finally, this review also discusses use of 1D MOS materials for emerging and novel electronic nose applications.

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Low temperature and fast response hydrogen gas sensor with Pd coated SnO2 nanofiber rods

Cited by 90 publications

References 44 publications

Synthesis and Screen Printing of Dopant Free Nano-crystalline SnO2 (101) Thick Film for Gas Sensor Application

Synthesis and Screen Printing of Dopant Free Nano-crystalline SnO2 (101) Thick Film for Gas Sensor Application

High-Performance Nanostructured Palladium-Based Hydrogen Sensors—Current Limitations and Strategies for Their Mitigation

1D Metal Oxide Semiconductor Materials for Chemiresistive Gas Sensors: A Review

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