5C-5 High Frequency Piezo Composites Microfabricated Ultrasound Transducers for Intravascular Imaging (Invited)

“…By using triangular pillars, it is possible to operate the fundamental excitation mode within the bandwidth of lateral modes. This study suggests that at high frequencies, triangularpillar composites allow for aspect ratios to be used that are well outside the acceptable range for low-frequency transducers [12]- [16] but can still produce acceptable performance at high frequencies. Essentially, the secondary modes are suppressed not by the conventional method of pushing the modes outside of the operating bandwidth, but by instead spreading the lateral mode energy out over a wide frequency range within the operating bandwidth of the transducer.…”

“…at high frequencies, it is very difficult, using conventional diceand-fill techniques, to sufficiently reduce the size/spacing of the composite pillars enough to push the lateral resonances outside the operating bandwidth of the transducer. For example, to push the first lamb-mode frequency as defined by reynolds et al [8] to about 80 MHz (twice the fundamental frequency [16]), while still maintaining a volume fraction of piezoelectric above 25%, a kerf width of approximately 6 μm is required (assuming a typical piezoelectric and epoxy filler). Because the minimum blade width on our dicing saw is 15 μm, lateral resonances are of great concern for center frequencies greater than about 20 MHz.…”

“…The optimal pillar widths actually approach the dimensions of the ceramic grain size, and the smallest dicing saw blade/laser spot sizes that are currently available are too large to create composites with high enough volume fractions. There has, however, been some interesting work with reducing pillar sizes and increasing volume fractions in pMn-pT single crystal transducers using reactive ion etching [16] and also some interesting work in increasing volume fractions by interdigital bonding [17]. However, generally, decreasing the pillar dimensions in conventional dice-and-fill ceramic composites has hit a plateau.…”

Fabrication and performance of high-frequency composite transducers with triangular-pillar geometry

“…By using triangular pillars, it is possible to operate the fundamental excitation mode within the bandwidth of lateral modes. This study suggests that at high frequencies, triangularpillar composites allow for aspect ratios to be used that are well outside the acceptable range for low-frequency transducers [12]- [16] but can still produce acceptable performance at high frequencies. Essentially, the secondary modes are suppressed not by the conventional method of pushing the modes outside of the operating bandwidth, but by instead spreading the lateral mode energy out over a wide frequency range within the operating bandwidth of the transducer.…”

“…at high frequencies, it is very difficult, using conventional diceand-fill techniques, to sufficiently reduce the size/spacing of the composite pillars enough to push the lateral resonances outside the operating bandwidth of the transducer. For example, to push the first lamb-mode frequency as defined by reynolds et al [8] to about 80 MHz (twice the fundamental frequency [16]), while still maintaining a volume fraction of piezoelectric above 25%, a kerf width of approximately 6 μm is required (assuming a typical piezoelectric and epoxy filler). Because the minimum blade width on our dicing saw is 15 μm, lateral resonances are of great concern for center frequencies greater than about 20 MHz.…”

“…The optimal pillar widths actually approach the dimensions of the ceramic grain size, and the smallest dicing saw blade/laser spot sizes that are currently available are too large to create composites with high enough volume fractions. There has, however, been some interesting work with reducing pillar sizes and increasing volume fractions in pMn-pT single crystal transducers using reactive ion etching [16] and also some interesting work in increasing volume fractions by interdigital bonding [17]. However, generally, decreasing the pillar dimensions in conventional dice-and-fill ceramic composites has hit a plateau.…”

Fabrication and performance of high-frequency composite transducers with triangular-pillar geometry

“…1 Over the past decade, significant progresses have been achieved on crystal growth and characterization, [2][3][4][5][6] and new applications [7][8][9][10][11][12][13][14][15] for binary PMN-PT crystals. Despite the excellent properties of PMN-PT single crystals, the relatively low depoling temperature (T R=T 75-97 C), low coercive field (E C 2:5 kV/cm) and low mechanical quality factor (Q M 80) remain concerns for many applications especially those require high drive conditions.…”

Crystal growth and property characterization for PIN–PMN–PT ternary piezoelectric crystals

“…This fabrication process was successfully developed by Jiang et al for fabricating high frequency piezoelectric composites as micro-ultrasound transducers. 16,17 A thick layer of nickel was electroplated through the photoresist pattern, forming the hard mask for the further dry etching step, which involved the deep reactive ion etching with chlorine based gases. However, this method is labor intensive and expensive due to the low etching rate and multiple processing steps.…”

Fabrication and measurement of a flexoelectric micro-pyramid composite