Your search keyword '"predictive thermal model"' showing total 5 results

1. Dataset of the Optimization of a Low Power Chemoresistive Gas Sensor: Predictive Thermal Modelling and Mechanical Failure Analysis

Author

Andrea Gaiardo, David Novel, Elia Scattolo, Alessio Bucciarelli, Pierluigi Bellutti, and Giancarlo Pepponi

Subjects

silicon microheaters, chemoresistive gas sensors, predictive thermal model, mechanical failure analysis, response surface method, Bibliography. Library science. Information resources

Abstract

Over the last few years, employment of the standard silicon microfabrication techniques for the gas sensor technology has allowed for the development of ever-small, low-cost, and low-power consumption devices. Specifically, the development of silicon microheaters (MHs) has become well established to produce MOS gas sensors. Therefore, the development of predictive models that help to define a priori the optimal design and layout of the device have become crucial, in order to achieve both low power consumption and high mechanical stability. In this research dataset, we present the experimental data collected to develop a specific and useful predictive thermal-mechanical model for high performing silicon MHs. To this aim, three MH layouts over three different membrane sizes were developed by using the standard silicon microfabrication process. Thermal and mechanical performances of the produced devices were experimentally evaluated, by using probe stations and mechanical failure analysis, respectively. The measured thermal curves were used to develop the predictive thermal model towards low power consumption. Moreover, a statistical analysis was finally introduced to cross-correlate the mechanical failure results and the thermal predictive model, aiming at MH design optimization for gas sensing applications. All the data collected in this investigation are shown.

Published

2021

2. Optimization of a Low-Power Chemoresistive Gas Sensor: Predictive Thermal Modelling and Mechanical Failure Analysis

Author

Andrea Gaiardo, David Novel, Elia Scattolo, Michele Crivellari, Antonino Picciotto, Francesco Ficorella, Erica Iacob, Alessio Bucciarelli, Luisa Petti, Paolo Lugli, and Alvise Bagolini

Subjects

silicon microheaters, chemoresistive gas sensors, predictive thermal model, mechanical failure analysis, response surface method, Chemical technology, TP1-1185

Abstract

The substrate plays a key role in chemoresistive gas sensors. It acts as mechanical support for the sensing material, hosts the heating element and, also, aids the sensing material in signal transduction. In recent years, a significant improvement in the substrate production process has been achieved, thanks to the advances in micro- and nanofabrication for micro-electro-mechanical system (MEMS) technologies. In addition, the use of innovative materials and smaller low-power consumption silicon microheaters led to the development of high-performance gas sensors. Various heater layouts were investigated to optimize the temperature distribution on the membrane, and a suspended membrane configuration was exploited to avoid heat loss by conduction through the silicon bulk. However, there is a lack of comprehensive studies focused on predictive models for the optimization of the thermal and mechanical properties of a microheater. In this work, three microheater layouts in three membrane sizes were developed using the microfabrication process. The performance of these devices was evaluated to predict their thermal and mechanical behaviors by using both experimental and theoretical approaches. Finally, a statistical method was employed to cross-correlate the thermal predictive model and the mechanical failure analysis, aiming at microheater design optimization for gas-sensing applications.

Published

2021

3. Optimization of a Low-Power Chemoresistive Gas Sensor: Predictive Thermal Modelling and Mechanical Failure Analysis

Author

Erica Iacob, Antonino Picciotto, David Novel, Paolo Lugli, Francesco Ficorella, Luisa Petti, Elia Scattolo, Alvise Bagolini, Alessio Bucciarelli, Michele Crivellari, and Andrea Gaiardo

Subjects

Microheater, Materials science, Silicon, mechanical failure analysis, Mechanical engineering, chemistry.chemical_element, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, response surface method, Article, Analytical Chemistry, chemoresistive gas sensors, predictive thermal model, Thermal, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Microelectromechanical systems, Heating element, 010401 analytical chemistry, silicon microheaters, 021001 nanoscience & nanotechnology, Thermal conduction, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Nanolithography, chemistry, 0210 nano-technology, Microfabrication

Abstract

The substrate plays a key role in chemoresistive gas sensors. It acts as mechanical support for the sensing material, hosts the heating element and, also, aids the sensing material in signal transduction. In recent years, a significant improvement in the substrate production process has been achieved, thanks to the advances in micro- and nanofabrication for micro-electro-mechanical system (MEMS) technologies. In addition, the use of innovative materials and smaller low-power consumption silicon microheaters led to the development of high-performance gas sensors. Various heater layouts were investigated to optimize the temperature distribution on the membrane, and a suspended membrane configuration was exploited to avoid heat loss by conduction through the silicon bulk. However, there is a lack of comprehensive studies focused on predictive models for the optimization of the thermal and mechanical properties of a microheater. In this work, three microheater layouts in three membrane sizes were developed using the microfabrication process. The performance of these devices was evaluated to predict their thermal and mechanical behaviors by using both experimental and theoretical approaches. Finally, a statistical method was employed to cross-correlate the thermal predictive model and the mechanical failure analysis, aiming at microheater design optimization for gas-sensing applications.

Published

2021

4. Dataset of the Optimization of a Low Power Chemoresistive Gas Sensor: Predictive Thermal Modelling and Mechanical Failure Analysis

Author

Alessio Bucciarelli, Giancarlo Pepponi, Pierluigi Bellutti, Andrea Gaiardo, Elia Scattolo, and David Novel

Subjects

Optimal design, Information Systems and Management, Silicon, Computer science, mechanical failure analysis, chemistry.chemical_element, 02 engineering and technology, response surface method, 01 natural sciences, Automotive engineering, chemoresistive gas sensors, predictive thermal model, Thermal, 010401 analytical chemistry, Process (computing), silicon microheaters, Experimental data, 021001 nanoscience & nanotechnology, lcsh:Z, lcsh:Bibliography. Library science. Information resources, 0104 chemical sciences, Computer Science Applications, Power (physics), chemistry, A priori and a posteriori, 0210 nano-technology, Information Systems, Microfabrication

Abstract

Over the last few years, employment of the standard silicon microfabrication techniques for the gas sensor technology has allowed for the development of ever-small, low-cost, and low-power consumption devices. Specifically, the development of silicon microheaters (MHs) has become well established to produce MOS gas sensors. Therefore, the development of predictive models that help to define a priori the optimal design and layout of the device have become crucial, in order to achieve both low power consumption and high mechanical stability. In this research dataset, we present the experimental data collected to develop a specific and useful predictive thermal-mechanical model for high performing silicon MHs. To this aim, three MH layouts over three different membrane sizes were developed by using the standard silicon microfabrication process. Thermal and mechanical performances of the produced devices were experimentally evaluated, by using probe stations and mechanical failure analysis, respectively. The measured thermal curves were used to develop the predictive thermal model towards low power consumption. Moreover, a statistical analysis was finally introduced to cross-correlate the mechanical failure results and the thermal predictive model, aiming at MH design optimization for gas sensing applications. All the data collected in this investigation are shown.

Published

2021

5. Optimization of a Low-Power Chemoresistive Gas Sensor: Predictive Thermal Modelling and Mechanical Failure Analysis.

Author

Gaiardo, Andrea, Novel, David, Scattolo, Elia, Crivellari, Michele, Picciotto, Antonino, Ficorella, Francesco, Iacob, Erica, Bucciarelli, Alessio, Petti, Luisa, Lugli, Paolo, Bagolini, Alvise, and Llobet, Eduard

Subjects

*FAILURE analysis, *MECHANICAL failures, *MECHANICAL models, *PREDICTION models, *MANUFACTURING processes, *PROTON conductivity

Abstract

The substrate plays a key role in chemoresistive gas sensors. It acts as mechanical support for the sensing material, hosts the heating element and, also, aids the sensing material in signal transduction. In recent years, a significant improvement in the substrate production process has been achieved, thanks to the advances in micro- and nanofabrication for micro-electro-mechanical system (MEMS) technologies. In addition, the use of innovative materials and smaller low-power consumption silicon microheaters led to the development of high-performance gas sensors. Various heater layouts were investigated to optimize the temperature distribution on the membrane, and a suspended membrane configuration was exploited to avoid heat loss by conduction through the silicon bulk. However, there is a lack of comprehensive studies focused on predictive models for the optimization of the thermal and mechanical properties of a microheater. In this work, three microheater layouts in three membrane sizes were developed using the microfabrication process. The performance of these devices was evaluated to predict their thermal and mechanical behaviors by using both experimental and theoretical approaches. Finally, a statistical method was employed to cross-correlate the thermal predictive model and the mechanical failure analysis, aiming at microheater design optimization for gas-sensing applications. [ABSTRACT FROM AUTHOR]

Published

2021