Design and simulation of interdigitated electrode for Graphene-SnO2 sensor on acetone gas

Hikmah, Nur; Hawari, Huzein Fahmi; Gupta, Monika

doi:10.11591/ijeecs.v19.i1.pp119-125

Cited by 5 publications

(3 citation statements)

References 25 publications

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“…They got struck impacts by combining backslide counts with electronic nose guarantees [20]. Hikmah et al also mentioned the z-nose in a study that determines the type of food [21].…”

Section: Discussionmentioning

confidence: 99%

Detection of harmful gases present in the environment

Rai

Saeed

2023

IJEECS

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The electronic nose (e-nose) is demonstrated in this research for detecting and identifying several forms of hazardous gases. We describe an e-noses for detecting several gases, including butane, acetone, methane, and ethanol. For dimensionality reduction in 3D representation, data processing approaches are based on the partial least square (PLS) method. The suggested system can be utilised for sensor optimization since different sensors with varied operating temperatures can be tested in many devices to find the best array for a specific detection or application. The results reveal that, depending on the sensor array characteristics, varying success rates in classification can be attained when discriminating contaminants. The preceding criteria lead to a new search for a portable, dependable, low-cost, and most efficient gas sensor. The major purpose of this study is to create a gas sensor array that can detect and monitor toxic and poisonous gases in the environment, as well as warn against dangerous organic compounds. Our goal is to create a sensor system that can distinguish the most significant decontamination gases while also being highly responsive, precise, low-effort, and low-power demanding.

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“…They got struck impacts by combining backslide counts with electronic nose guarantees [20]. Hikmah et al also mentioned the z-nose in a study that determines the type of food [21].…”

Section: Discussionmentioning

confidence: 99%

Detection of harmful gases present in the environment

Rai

Saeed

2023

IJEECS

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“…47 When the sensor is exposed to NH 3 gas by static volumetric method, O d− on the surface interacts with NH 3 in a redox reaction, releasing captured electrons back into WO 3 . 48 The electrons are transported smoothly out as the thickness of the space charge layers and barrier height decrease, thereby recovering the resistance of the material. 49,50 NH 3 molecules react with oxygen ions on the surface according to the following reaction: For the TW sensor, the enhancement of the NH 3 sensing performance due to TiO 2 decoration is attributed to the heterojunction effect between different semiconductor materials.…”

mentioning

confidence: 99%

A high-performance room-temperature NH₃ gas sensor based on WO₃/TiO₂ nanocrystals decorated with Pt NPs

Wu,

Chen,

Deng

et al. 2024

RSC Adv.

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“…The structure of the IDE essentially creates a network of parallel resistors which is difficult to model analytically [26]. Simulations of graphene IDEs are possible using COMSOL [27], however, simulations for graphene devices are out of the scope of this thesis, as the focus is on design and simulation of the interface.…”

Section: Idementioning

confidence: 99%

Platform for Graphene Sensors Using Printed Circuit Boards and Single Board Computers

Galeote¹

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A platform was designed to allow electrical measurements to be taken from graphene sensors without the need for a probing bench or other lab equipment.Research began with the characterization of a range of different sensors, including various types of graphene field-effect transistors (GFET), interdigitated electrodes (IDE), and Hall sensors. Out of all the dropcast FETs that were tested, 23.6% were within a 20% margin of the expected resistance. Testing for Hall sensors involved measuring resistivity and hall coefficient on a set of two bars that were perpendicular to the direction of the current. 9 out of the 64 hall sensors tested had resistivity and hall coefficients that were within 10% of each other on each bar. A selection of sensors, namely the hall, dropcast GFET (or "droplet"), and infrared sensors then had circuit boards designed to house them. The PCBs were designed to be connected to the GPIO of a Raspberry Pi, which could then supply voltage and read measurements using a MATLAB script. The hall and droplet sensors had two variants designed for them, one with fewer components to be used in conjunction with an ADC expansion board for the Raspberry Pi, and a more complex board with an on-board ADC. ADC variants for the boards were simulated in LTspice, while testing of the platform was done with a Graphenea S20 GFET chip mounted on one of the IR boards and included a breadboard and resistor to create a voltage divider. After initial calibration, resistance measurements from the Raspberry pi were accurate within 1% to those taken with a semiconductor parameter analyzer.iii A method was developed to successfully refresh the graphene with acetone without damaging the PCB, raising the resistance of the GFETs by 701Ω on average.Results from using wax encapsulation to slow or stop resistance drift are inconclusive, the chip with wax had average resistance that shifted −40.1Ω to +25.5Ω per day, while the resistance drift on the chip without wax was −75.4Ω to +52.2Ω per day.There are several people who I would like to thank for the assistance that they have provided me while completing this work, whether in the form of inspiration, knowledge, finances, or labor.First and foremost I would like to thank my supervisor, Rony Amaya, for the guidance and support that I have received throughout this research.I would like to thank Brian Kennedy for supplying the graphene sensors used in this project, as well as funding for the research. Wenyu Zhou for designing most of the sensors used in this research and providing the information needed to test them and integrate them with the larger system. As well as Daniel Christakos for assistance in verifying the hardware and software.Waqar Ahmad and Otto Benedeczky for helping me learn how to use Altium Designer and giving tips on reducing board costs. Nagui Mikhail for getting me set up in the lab at Carleton, and supplying me with the equipment I needed for sensor characterization. Robert Vandusen for helping to develop and perform the acetone wash and wax encapsulation/remo...

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Design and simulation of interdigitated electrode for Graphene-SnO2 sensor on acetone gas

Cited by 5 publications

References 25 publications

Detection of harmful gases present in the environment

Detection of harmful gases present in the environment

A high-performance room-temperature NH₃ gas sensor based on WO₃/TiO₂ nanocrystals decorated with Pt NPs

Platform for Graphene Sensors Using Printed Circuit Boards and Single Board Computers

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Design and simulation of interdigitated electrode for Graphene-SnO2 sensor on acetone gas

Cited by 5 publications

References 25 publications

Detection of harmful gases present in the environment

Detection of harmful gases present in the environment

A high-performance room-temperature NH3 gas sensor based on WO3/TiO2 nanocrystals decorated with Pt NPs

Platform for Graphene Sensors Using Printed Circuit Boards and Single Board Computers

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Product

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A high-performance room-temperature NH₃ gas sensor based on WO₃/TiO₂ nanocrystals decorated with Pt NPs