2011
DOI: 10.1007/s10832-011-9639-6
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High-temperature piezoelectric crystals and devices

Abstract: Conventional piezoelectric materials such as quartz are widely used as high precision transducers and sensors based on bulk acoustic waves. However, their operation temperature is limited by the intrinsic materials properties to about 500 • C. High-temperature applications are feasible by applying materials that retain their piezoelectric properties up to higher temperatures. Here, langasite (La 3 Ga 5 SiO 14 ) and compounds of the langasite family are the most promising candidates, since they are shown to exh… Show more

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Cited by 74 publications
(65 citation statements)
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References 93 publications
(169 reference statements)
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“…Resonance measurements have been reported at temperatures up to 1400 °C for a variety of materials including lead titanate based relaxors up to 150 °C [35], commercial lead-and bismuth-based ceramics up to 500 °C [36], lithium-sodium niobate ceramics up to 800 °C [37], ordered langasite crystals up to 900 °C [38], rare earth calcium oxyborate single crystal (YCOB) up to 950 °C [39] and 1000 °C [40], langasite and -quartz crystals up to 1400 °C [41] [42]. For high quality crystals at moderate temperatures, the standard (low loss) method can be applied directly with no account taken of the effects of the losses, but this is unlikely to be the case particularly for many perovskite lead and bismuth based piezoelectrics even at moderately elevated temperatures.…”
Section: High Temperature Piezoelectric Resonancementioning
confidence: 99%
“…Resonance measurements have been reported at temperatures up to 1400 °C for a variety of materials including lead titanate based relaxors up to 150 °C [35], commercial lead-and bismuth-based ceramics up to 500 °C [36], lithium-sodium niobate ceramics up to 800 °C [37], ordered langasite crystals up to 900 °C [38], rare earth calcium oxyborate single crystal (YCOB) up to 950 °C [39] and 1000 °C [40], langasite and -quartz crystals up to 1400 °C [41] [42]. For high quality crystals at moderate temperatures, the standard (low loss) method can be applied directly with no account taken of the effects of the losses, but this is unlikely to be the case particularly for many perovskite lead and bismuth based piezoelectrics even at moderately elevated temperatures.…”
Section: High Temperature Piezoelectric Resonancementioning
confidence: 99%
“…The crystals exhibit mixed electronic and ionic conductivity, which contributes to the loss at high temperatures. The oxygen partial pressure-dependent conductivity impacts the performance of the resonators in a minor way as long as the oxygen partial pressure is kept, e.g., above 10 −20 bar at 600 • C Fritze, 2006Fritze, , 2011a.…”
Section: Introductionmentioning
confidence: 99%
“…Long AlN crystals grow for several dozens of hours and often in several runs. The evolution of the crystal quality via the improvement of the growth regime from the 2-inch diameter 10 mm long bulk AlN crystal having a single-crystal core of about 40 mm diameter and a polycrystalline rim (Avdeev et al, 2010;2011) to the "good enough" single crystal (and, hence, the substrate) is illustrated by Fig. 12.…”
Section: Growth Of Bulk Aln Crystals Starting From Aln Seedsmentioning
confidence: 99%