A Self‐Powered Portable Nanowire Array Gas Sensor for Dynamic NO<sub>2</sub> Monitoring at Room Temperature

Wei, Shiyu; Li, Zhe; Murugappan, Krishnan; Li, Ziyuan; Zhang, Fanlu; Saraswathyvilasam, Aswani Gopakumar; Lysevych, Mykhaylo; Tan, Hark Hoe; Jagadish, Chennupati; Tricoli, Antonio; Fu, Lan

doi:10.1002/adma.202207199

Cited by 28 publications

(19 citation statements)

References 54 publications

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“…For example, they can be affixed to road traffic signs and advertising boards for monitoring NO 2 on traffic roads. 70 Sensors mounted on face masks, fabrics, etc. can be well applied to monitor gas pollutants in daily life, providing new ideas for healthcare monitoring.…”

Section: Acsmentioning

confidence: 99%

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors

Lu,

Zong,

Tao

et al. 2024

ACS Sens.

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Conductive metal−organic frameworks (MOFs) have received increasing attention in recent years and present high application potential as sensing elements in electronic sensors. In this study, flexible field-effect transistor (FET) sensors based on conductive MOF, i.e., Ni 3 (HHTP) 2 , have been constructed. This Ni 3 (HHTP) 2 sensor has high sensitivity (detection limit of 56 ppb) as well as superior selectivity for NO 2 detection at room temperature, which is demonstrated by accurate gas detection in a mixed gas atmosphere. Moreover, by employing six flexible substrates, i.e., polyimide (PI), tape (PET), facemask, paper cup, tablecloth, and take-out bag (textile), we successfully demonstrate the universality of the flexible sensor construction with conductive MOF as sensing film on various substrates. This study of conductive MOF-based flexible electronic sensors offers a new opportunity for a wide range of sensing applications with wearable and portable electronic devices.

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Section: Acsmentioning

confidence: 99%

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors

Lu,

Zong,

Tao

et al. 2024

ACS Sens.

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“…This is why we need to develop nanoscale gas sensors, consistent with the experimental observations in literature. [8][9][10][11][12][13][14][15][16][17][18][19][20] Figure 3c depicts the experimental sensitivities. Overall, the sensitivity decreases at higher analyte concentration.…”

Section: Note That Si Nws Have the Poorest Responses And Smallest 𝛾mentioning

confidence: 99%

“…Chemical gas sensors have found a wide range of applications in defense, [1][2][3] safety, and disease diagnosis. [4][5][6][7] To enhance sensitivity, low-dimensional materials such as nanoparticles, [8][9][10][11] polycrystalline thin films, [12][13][14] chemical-vapor-deposited nanowires (NWs) [15][16][17] and 2D atomically thin materials [18][19][20] are often used as gas sensors due to their high surface-to-volume ratio (SVR) compared with bulk material. Although the sensing mechanism of chemiresistive gas sensor has been extensively investigated, [21][22][23][24] an analytical gas-sensing formula that allows for designing gas sensors and predicting sensor responses has yet to be established due to the challenges to control the dimensionality, surface states, and crystal quality of these lowdimensional materials.…”

Section: Introductionmentioning

confidence: 99%

Analytical Gas‐Sensing Responses for Single‐Crystalline Semiconducting Gas Sensors

Liu,

Li,

et al. 2023

Advanced Sensor Research

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In this study, an analytical gas response formula is developed based on the classical gaseous molecule adsorption model. To validate the analytical formula, an array of silicon nanowires or microwires is fabricated by patterning the device layer of a silicon‐on‐insulator (SOI) wafer. Gas Hall effect measurements reveal that the surface depletion of the wires narrows down upon exposure to polar molecules that act as dipoles to partially neutralize the surface charges. Gas conductance measurements are performed on different sizes of wires at elevated temperatures. The responses on exposure to different concentrations of water, acetone, and ethanol vapors can be well fitted with the analytical gas response formula. The extracted parameters are consistent with their physical nature. Additionally, the established analytical gas response formula can also well fit gas responses of single‐crystalline nanowires in literature, which further validates the analytical formula.

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“…The selection of this spectral window was made for two reasons: firstly, the laser beam is not attenuated by the water droplets in high-humidity conditions, and, secondly, the telecom C band around 1550 nm has a multitude of off-the-shelf components which can be used to create low-cost gas sensors. Recent reports [ 37 ], in which InP nanowire arrays are used to monitor NO

at room temperature by measuring an electrical signal have provided a significant level of insight in the realization of NO

gas sensors in typical ambient environments. Our method differs from the former due to the fact that our sensor is designed for use in humid and wet environments, where the recording of small-level electrical signals can become challenging.…”

Section: Introductionmentioning

confidence: 99%

Towards Highly Efficient Nitrogen Dioxide Gas Sensors in Humid and Wet Environments Using Triggerable-Polymer Metasurfaces

Dănilă

Gross

2023

Polymers

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We report simulations on a highly-sensitive class of metasurface-based nitrogen dioxide (NO2) gas sensors, operating in the telecom C band around the 1550 nm line and exhibiting strong variations in terms of the reflection coefficient after assimilation of NO2 molecules. The unit architecture employs a polymer-based (polyvinylidene fluoride—PVDF or polyimide—PI) motif of either half-rings, rods, or disks having selected sizes and orientations, deposited on a gold substrate. On top of this, we add a layer of hydrophyllic polymer (POEGMA) functionalized with a NO2-responsive monomer (PAPUEMA), which is able to adsorb water molecules only in the presence of NO2 molecules. In this process, the POEGMA raises its hidrophyllicity, while not triggering a phase change in the bulk material, which, in turn, modifies its electrical properties. Contrary to absorption-based gas detection and electrical signal-based sensors, which experience considerable limitations in humid or wet environments, our method stands out by simple exploitation of the basic material properties of the functionalized polymer. The results show that NO2-triggered water molecule adsorption from humid and wet environments can be used in conjunction with our metasurface architecture in order to provide a highly-sensitive response in the desired spectral window. Additionally, instead of measuring the absorption spectrum of the NO2 gas, in which humidity counts as a parasitic effect due to spectral overlap, this method allows tuning to a desired wavelength at which the water molecules are transparent, by scaling the geometry and thicknesses of the layers to respond to a desired wavelength. All these advantages make our proposed sensor architecture an extremely-viable candidate for both biological and atmospheric NO2 gas-sensing applications.

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A Self‐Powered Portable Nanowire Array Gas Sensor for Dynamic NO₂ Monitoring at Room Temperature

Cited by 28 publications

References 54 publications

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors

Analytical Gas‐Sensing Responses for Single‐Crystalline Semiconducting Gas Sensors

Towards Highly Efficient Nitrogen Dioxide Gas Sensors in Humid and Wet Environments Using Triggerable-Polymer Metasurfaces

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A Self‐Powered Portable Nanowire Array Gas Sensor for Dynamic NO2 Monitoring at Room Temperature

Cited by 28 publications

References 54 publications

High-Performance Ni3(HHTP)2 Film-Based Flexible Field-Effect Transistor Gas Sensors

High-Performance Ni3(HHTP)2 Film-Based Flexible Field-Effect Transistor Gas Sensors

Analytical Gas‐Sensing Responses for Single‐Crystalline Semiconducting Gas Sensors

Towards Highly Efficient Nitrogen Dioxide Gas Sensors in Humid and Wet Environments Using Triggerable-Polymer Metasurfaces

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Product

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A Self‐Powered Portable Nanowire Array Gas Sensor for Dynamic NO₂ Monitoring at Room Temperature

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors

High-Performance Ni₃(HHTP)₂ Film-Based Flexible Field-Effect Transistor Gas Sensors