B. van der Schoot scite author profile

We have performed thermal measurements and electrothermal simulations (finite element modelling) with the aim of optimizing the power consumption and the temperature distribution of micro-hotplates for gas-sensing applications. A silicon island was added underneath the membrane of the micro-hotplate to improve the temperature distribution of drop-coated metal–oxide gas sensors and to thermally isolate MOSFET gas sensors. The temperature distribution over the sensing area and the power consumption depend on the silicon island thickness, which was optimized for both applications using the software MEMCAD from Microcosm Technologies. In the optimization process, we considered the thermal conductivity of silicon and dielectric membrane, the operating temperature, the geometry and the area of the heater, and the processing of the silicon island. The thickness of the silicon island was optimized to ensure a good temperature distribution over the gas-sensing area for metal–oxide and MOSFET gas sensors with specific geometry.

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A low-power micromachined MOSFET gas sensor

Briand

Schoot

Rooij

et al. 2000

J. Microelectromech. Syst.

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This paper reports on the design, fabrication, and characterization of the first low-power consumption MOSFET gas sensor. The novel MOSFET array gas sensor has been fabricated using anisotropic bulk silicon micromachining. A heating resistor, a diode used as temperature sensor, and four MOSFETs are located in a silicon island suspended by a dielectric membrane. The membrane has a low thermal conductivity coefficient and, therefore, thermally isolates the electronic components from the chip frame. This low thermal mass device allows the reduction of the power consumption to a value of 90 mW for an array of four MOSFETs at an operating temperature of 170 C. Three of the MOSFETs have their gate covered with thin catalytic metals and are used as gas sensors. The fourth one has a standard gate covered with nitride and could act as a reference. The sensor was tested under different gaseous atmospheres and has shown good gas sensitivities to hydrogen and ammonia. The low-power MOSFET array gas sensor presented is suitable for applications in portable gas sensor instruments, electronic noses, and automobiles. [534]

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Smallest dead volume microvalves for integrated chemical analyzing systems

Shoji

Schoot

Rooij

et al.

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B. van der Schoot

Design and fabrication of high-temperature micro-hotplates for drop-coated gas sensors

Comparison of the hysteresis of Ta2O5 and Si3N4 pH-sensing insulators

Thermal optimization of micro-hotplates that have a silicon island

A low-power micromachined MOSFET gas sensor

Smallest dead volume microvalves for integrated chemical analyzing systems

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