Micromachined SiO2 microcantilever for high sensitive moisture sensor

Chen, Qi; Fang, Ji; Ji, Hai‐Feng; Varahramyan, Kody

doi:10.1007/s00542-007-0489-8

Cited by 10 publications

(5 citation statements)

References 28 publications

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“…Curve fitting result shows that a deflection range of 0 to 2450nm in the fibre core area is achieved, which is more than we expected from our calculation above (shown in Fig.10). We believe that this is probably because the cantilever is not a perfect rectangular shape, with a profile that varies along its length the residual error of the cavity length calibrated by ML10 is 15nm to 20nm, demonstrating that our interrogation system is capable of detecting a cantilever deflection change down to a few nanometers, which should be suitable for bio-sensing applications [19][20]. …”

Section: Renishaw P0mentioning

confidence: 94%

Micro-machined optical fibre cantilever as sensor elements

Albri

Maier

et al. 2012

Micro-Optics 2012

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Micro-fabricated cantilevers have been reported recently as miniaturized, rapid response, ultrasensitive sensors elements suitable for various chemical and bio-sensing applications. However, the alignment of the cantilever with the optical read-out system can be challenging and typically involves a bulky free-space optical detection system. We propose using cantilevers aligned to the core of an optical fibre during the fabrication process to address this issue.Focussed Ion Beam (FIB) machining has been demonstrated as capable of fabricating fibre-top cantilevers. Here we demonstrate techniques to design and fabricate micro-cantilevers using a combination of laser machining and FIB processing to fabricate sensing cantilevers onto the end of standard and multi-core fibres (MCF). In this way the cantilever can be aligned with the core of the fibre therefore offering stable and accurate means of optically addressing the cantilever. Use of MCF offers the potential for a single probe capable of making multiple measurements in a confined measurement volume, to determine multiple species of interest, or to provide background reference measurements for example.The optical cavity formed between the fibre and the cantilever is monitored using low-cost optical sources and fibre coupled spectrometers to demonstrate a practical measurement system. This can readily achieve <50nm resolution using analysis based upon recovering the free spectral range using the Fast Fourier Transform to calculate the final cavity length.

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Section: Renishaw P0mentioning

confidence: 94%

Micro-machined optical fibre cantilever as sensor elements

Albri

Maier

et al. 2012

Micro-Optics 2012

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“…Such systems possess many advantages compared to their traditional large-scale counterparts, including amongst other things lower power consumption, a higher precision, a more rapid response, an improved portability, and a lower manufacturing cost. Importantly, the functionality and reliability of these micro-sensors can be enhanced through their integration with mature logic IC technology or with other micro-scale devices (Yamazoe 2005;Velanki and Ji 2006;Korotcenkov 2007;Choudhury et al 2007;Tuomas et al 2008;Chen et al 2008;Wang et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Design and characterization of MEMS-based flow-rate and flow-direction microsensor

Lee

Wen

Hou

et al. 2009

Microfluid Nanofluid

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This study designs and characterizes a novel MEMS-based flow-rate micro-sensor consisting of a platinum resistor deposited on a silicon nitride-coated silicon cantilever beam. Due to the difference between the thermal conductivities of the silicon nitride film and the silicon beam, the tip of the cantilever structure bends slightly in the upward direction. As air travels across the upper surface of the sensor, it interferes with the curved tip and displaces the beam in either the upward or the downward direction. The resulting change in the resistor signal is then used to calculate the velocity of the air. A flow-direction micro-sensor is constructed by arranging eight cantilever structures on an octagonal platform. Each cantilever is separated from its neighbors by a tapered baffle plate connected to a central octagonal pillar designed to attenuate the aerodynamic force acting on the cantilever beams. By measuring the resistor signals of each of the cantilever beams, the micro-sensor is capable of measuring both the flow rate and the flow direction of the air passing over the sensor. A numerical investigation is performed to examine the effects of the pillar height and pillar-to-tip gap on the airflow distribution, the pressure distribution, the bending moment acting on each beam, and the sensor sensitivity. The results show that the optimum sensor performance is obtained using a pillar height of 0.75 mm and a pillar-to-tip gap of 5 mm. Moreover, the sensitivity of the octagonal sensing platform is found to be approximately 90% that of a single cantilever beam.

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“…The polyimide capacitive humidity sensor showed a sensitivity of 0.77 pF/RH%. Chen et al [ 6 ] proposed a humidity microsensor with a micromachined silicon dioxide cantilever beam. The fabrication of the sensor combined the isotropic and anisotropic dry etching of inductively couple plasma to release the silicon dioxide cantilever beam.…”

Section: Introductionmentioning

confidence: 99%

Titanium Dioxide Nanoparticle Humidity Microsensors Integrated with Circuitry on-a-Chip

Dai

Hsu

2014

Sensors

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Abstract:A humidity microsensor integrated with a readout circuit on-a-chip fabricated using the commercial 0.18 μm CMOS (complementary metal oxide semiconductor) process was presented. The integrated sensor chip consists of a humidity sensor and a readout circuit. The humidity sensor is composed of a sensitive film and interdigitated electrodes. The sensitive film is titanium dioxide prepared by the sol-gel method. The titanium dioxide is coated on the interdigitated electrodes. The humidity sensor requires a post-process to remove the sacrificial layer and to coat the titanium dioxide. The resistance of the sensor changes as the sensitive film absorbs or desorbs vapor. The readout circuit is employed to convert the resistance variation of the sensor into the output voltage. The experimental results show that the integrated humidity sensor has a sensitivity of 4.5 mV/RH% (relative humidity) at room temperature.

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Micromachined SiO2 microcantilever for high sensitive moisture sensor

Cited by 10 publications

References 28 publications

Micro-machined optical fibre cantilever as sensor elements

Micro-machined optical fibre cantilever as sensor elements

Design and characterization of MEMS-based flow-rate and flow-direction microsensor

Titanium Dioxide Nanoparticle Humidity Microsensors Integrated with Circuitry on-a-Chip

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