Analytical model of a SAW gas sensor

Urbańczyk, M.

doi:10.2495/cmem110431

Cited by 3 publications

(7 citation statements)

References 13 publications

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“…Figures 6-9 present exemplary results of the analysis in unsteady state concerning the sensor layer of WO 3 . The chosen representative gas was hydrogen, the properties of which have been investigated comprehensively in [3][4][5][6][7]. As can be seen in Fig.…”

Section: Results Of the Numerical Analysismentioning

confidence: 99%

“…Of no less importance is also the matching of a mathematical model to the achieved experimental results. These papers suggest a theoretical model as well as numerical analyses of a gas sensor of surface acoustic wave (SAW) type [1][2][3][4][5][6][7][8][9][10], in its steady state. As the phenomenon of the acoustoelectric effect depends in the set of a semiconducting layer and piezoelectric acoustic waveguide on the profile of the distribution of concentrations of the charge carriers in the sensor layer, it has been suggested to divide the sensor layer into thin sublayers, assuming a constant concentration of the carriers in these sublayers, alternating in each subsequent sublayer situated at different distances from the acoustic waveguide.…”

Section: Introductionmentioning

confidence: 99%

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Analysis of Non-Steady Stage in SAW Gas Sensors with Semiconducting Sensor Layers

Urbańczyk

Hejczyk

2011

Acta Phys. Pol. A

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The profile of the gas concentration in the sensor layer can be expressed as a polynomial function involving the diffusion coefficient (D K ), semiconductor film thickness (h), rate constant (k), gas concentration outside the semiconductor film (C S ). Before reaching a steady state of the concentration profile, its behavior depends on a few factors as the distance from the piezoelectric surface, the rate constant, the thickness of the layer and the diffusion constant and time. We are going to simulate temporary processes in the semiconductor sensor film in the surface acoustic wave gas sensor system and to describe the influence on relative changes of the surface acoustic wave velocity. The numerical results basing on the code written in Pyton, are described and analyzed.

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Section: Results Of the Numerical Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analysis of Non-Steady Stage in SAW Gas Sensors with Semiconducting Sensor Layers

Urbańczyk

Hejczyk

2011

Acta Phys. Pol. A

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“…A stationary model (in the steady state) was supported by time dependences permitting research of dynamic characteristics of the SAW gas sensor (Urbanczyk, 2011a).…”

Section: Model Of the Saws Gas Sensor And Influencementioning

confidence: 99%

Numerical Analysis of Sensitivity of SAW Structure to the Effect of Toxic Gases

Hejczyk

Pustelny

Wszołek

et al. 2016

Archives of Acoustics

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The paper presents the results of numerical analysis of the SAW gas sensor in the steady and nonsteady states. The effect of SAW velocity changes vs surface electrical conductivity of the sensing layer is predicted. The conductivity of the porous sensing layer above the piezoelectric waveguide depends on the profile of the diffused gas molecule concentration inside the layer. The Knudsen's model of gas diffusion was used.Numerical results for the effect of gas CH4 on layers: WO3, TiO2, NiO, SnO2 in the steady state and CH4 in the non-steady state in recovery step in the WO3 sensing layer have been shown. The main aim of the investigation was to study thin film interaction with target gases in the SAW sensor configuration based on simple reaction-diffusion equation.The results of the numerical analysis allow to select the sensor design conditions, including the morphology of the sensor layer, its thickness, operating temperature, and layer type. The numerical results basing on the code elaborated numerical system (written in Python language), were analysed. The theoretical results were verified and confirmed experimentally.

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“…The intensity interaction of the electric field with a sensing layer in a surface wave sensor depends not only on the electrical conductivity of the layer, but also on its distance from the piezoelectric waveguide. More details about the analytical model can be found in the paper by Hejczyk and Urbańczyk [4][5][6][7][8][9]. Analyzing the acoustoelectric effect in a SAW sensor, the sensing layer was assumed to consist of n-thin sublayers (Fig.…”

Section: Analytical Model Of a Gas Sensormentioning

confidence: 99%

“…Using the transformation law for the n-th sublayer, it is possible to calculate the electrical admittance on the surface of the waveguide, which is "seen" by the surface wave. Then, the resultant of the admittance is used in Ingebrigtsen's formula [9][10][11] to determine the changes in the velocity of the surface wave resulting from the acoustoelectric interaction between the SAW and the sensor layer with a variable concentration of gas molecules in the y direction (in the depth of the layer). .…”

Section: Analytical Model Of a Gas Sensormentioning

confidence: 99%

SAW sensor for detection of hydrocarbons. Numerical analysis and experimental results

Hejczyk¹,

Urbańczyk²,

Wituła³

et al. 2012

Bulletin of the Polish Academy of Sciences: Technical Sciences

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Abstract. The paper presents the results of numerical analyses of the SAW gas sensor in the steady and non-steady state. The effect of SAW velocity changes vs. the surface electrical conductivity of the sensing layer is predicted. The conductivity of the porous sensing layer above the piezoelectric waveguide depends on the profile of the diffused gas molecule concentration inside the layer. Knudsen's model of gas diffusion was used. Numerical results for the gases CH4, C2H4, C3H8, C6H6 in the steady state and CH4 in the non-steady state in the WO3 sensing layer have been shown. The results of numerical analyzes allow to select the sensor design conditions, including the morphology of the sensor layer, its thickness and operating temperature. Some numerical results were verified in experimental studies concerning methane.

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Analytical model of a SAW gas sensor

Cited by 3 publications

References 13 publications

Analysis of Non-Steady Stage in SAW Gas Sensors with Semiconducting Sensor Layers

Analysis of Non-Steady Stage in SAW Gas Sensors with Semiconducting Sensor Layers

Numerical Analysis of Sensitivity of SAW Structure to the Effect of Toxic Gases

SAW sensor for detection of hydrocarbons. Numerical analysis and experimental results

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