Microthermomechanical infrared sensors

Steffanson, M.; Rangelow, Ivo W.

doi:10.2478/s11772-014-0176-0

Cited by 28 publications

(10 citation statements)

References 68 publications

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“…One method by which this may be done is by the cantilever as part of a capacitor [10]. By measuring changes in capacitance, the movement of the cantilever can be found.…”

Section: B Optomechanical Sensorsmentioning

confidence: 99%

Electronic Infrared Sensors

Conn¹

2019

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“…One method by which this may be done is by the cantilever as part of a capacitor [10]. By measuring changes in capacitance, the movement of the cantilever can be found.…”

Section: B Optomechanical Sensorsmentioning

confidence: 99%

Electronic Infrared Sensors

Conn¹

2019

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“…This out-of-plane motion can be sensed optically [7][8][9], or electrically through a piezoresistive material [10]. The latter suffers from temperature sensitivity concerns since the piezoresistive effect is inherently temperature dependent [11], while the former requires a bulky optical readout that is not suitable for emerging applications that need to be compact and low-cost [12]. A proposed third readout mechanism was introduced in [13], where the structure's head movement is measured capacitively.…”

Section: Introductionmentioning

confidence: 99%

Dual-Level Capacitive Micromachined Uncooled Thermal Detector

Tawfik

Allidina²,

Nabki

et al. 2019

Sensors

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This paper presents a novel dual-level capacitive microcantilever-based thermal detector that is implemented in the commercial surface micromachined PolyMUMPs technology. The proposed design is implemented side-by-side with four different single-level designs to enable a design-to-design performance comparison. The dual-level design exhibits a rate of capacitance change per degree Celsius that is over three times higher than that of the single-level designs and has a base capacitance that is more than twice as large. These improvements are achieved because the dual-level architecture allows a 100% electrode-to-detector area, while single-level designs are shown to suffer from an inherent trade-off between sensitivity and base capacitance. In single-level designs, either the number of the bimorph beams or the capacitance electrode can be increased for a given sensor area. The former is needed for a longer effective length of the bimorph for higher thermomechanical sensitivity (i.e., larger tilting angels per degree Celsius), while the latter is desired to relax the read-out integrated-circuits requirements. This thermomechanical response-to-initial capacitance trade-off is mitigated by the dual-level design, which dedicates one structural layer to serve as the upper electrode of the detector, while the other layer contains as many bimorph beams as desired, independently of the former’s area.

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“…17,[21][22][23][24][25] One recent and important application is their use is in waste energy harvesting for microelectric generators. The detected energy in the form of temperature rise is transformed into electrical pulses proportional to the temperature difference between the surfaces of the detector.…”

Section: Introductionmentioning

confidence: 99%

“…The uncooled pyroelectric infrared detectors are in great demand for many applications and a few of them are: atmospheric temperature measurement, earth position sensing, infrared detection, fire alarm operation, pollution detection, remote sensing, biomedical imaging etc. 17,[21][22][23][24][25] One recent and important application is their use is in waste energy harvesting for microelectric generators. 26 In this paper, we discuss the properties of TGS/PU and DTGS/PU composites for pyroelectric infrared detection applications.…”

Section: Introductionmentioning

confidence: 99%

Triglycine sulphate and its deuterated analog in polyurethane matrix for thermal/infrared detection: A comparison

Sudhakaran

Philip

2015

J of Applied Polymer Sci

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Composites comprising of polycrystalline triglycine sulphate (TGS) or its deuterated analog (DTGS) in powder form dispersed in polyurethane (PU) are synthesized for pyroelectric sensor applications. TGS and DTGS have high pyroelectric coefficients, but are susceptible to humidity, and PU is inherently electroactive. So composites made of TGS or DTGS dispersed in PU can be expected to have high pyroelectric coefficient as well as immunity to humidity. Composites with inclusion volume fraction between 0 and 0.25 are prepared, and their dielectric, pyroelectric, and thermal properties measured. In general, deuteration leads to decrease in dielectric constant and specific heat, but increase in thermal conductivity. The pyroelectric coefficient and figures of merit get enhanced significantly with deuteration as well as inclusion volume fraction. Comparison with similar composites shows that these samples have the highest values for figures of merit, indicating their potential use as thermal/infrared detectors that are immune to humidity.

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Microthermomechanical infrared sensors

Cited by 28 publications

References 68 publications

Electronic Infrared Sensors

Electronic Infrared Sensors

Dual-Level Capacitive Micromachined Uncooled Thermal Detector

Triglycine sulphate and its deuterated analog in polyurethane matrix for thermal/infrared detection: A comparison

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