ライフサイエンスコーパス: acoustic wave

1 tude lower than the frequency of the driving acoustic wave.

2 f magnitude smaller than that of the driving acoustic wave.

3 , is controlled by a radio frequency surface acoustic wave.

4 t to transient or continuous perturbation by acoustic waves.

5 heory applies equally to electromagnetic and acoustic waves.

6 ubstrate foil surface due to laser-generated acoustic waves.

7 icinity of the observer, and transduced into acoustic waves.

8 rk provides a different way for manipulating acoustic waves.

9 ur method uses tilted-angle standing surface acoustic waves.

10 has been demonstrated in electromagnetic and acoustic waves.

11 iate and cavitate bubbles in the presence of acoustic waves.

12 g the electrode geometry, we determined that acoustic waves alone are not responsible for poration of

13 Directing acoustic waves along curved paths is critical for applic

14 e principles and different configurations of acoustic wave and acoustic streaming for the manipulatio

15 These include: Bulk Acoustic Wave and Surface Acoustic Wave devices, micro-

16 By exploiting surface acoustic waves and a coupling layer technique, cells are

17 modes induced by the evanescent guided Lamb acoustic waves and remained Landau undamped due to fermi

18 itous at interfaces with optical, seismic or acoustic waves, and also with electron, neutron or atom

19 o far one of the very few examples of a bulk acoustic wave aptasensor that is able to directly detect

20 nals in 3D space because the X-ray generated acoustic waves are of a spherical nature and propagate i

21 ng pulsed piezoelectric transducer-generated acoustic waves at the surface of a liquid, resulting in

22 Here, we demonstrate standing surface acoustic wave based "acoustic tweezers" that can trap an

23 MEMS fabrication of acoustic wave based biosensors enables device miniaturiz

24 The acoustic wave based MEMS devices reported in the literat

25 This paper presents a review of acoustic-wave based MEMS devices that offer a promising

26 irable for improving the performance of many acoustic wave-based applications.

27 coustic waves in the system relative to bulk acoustic wave (BAW)-based actuation, which suppresses Ra

28 ted by the narrow-frequency bandwidth of the acoustic waves because of the large attenuation for high

29 henomena: highly nonlinear distortion of the acoustic wave before it hits the droplet and focusing of

30 evidence for the hydrodynamic nature of the acoustic wave/biomolecule interaction at a solid/liquid

31 st label-free real-time ultra-high frequency acoustic wave biosensor prototype capable of detecting t

32 and microfluidics are easily constructed for acoustic wave biosensors, such as the Love wave device d

33 cting objects, the evolution of the radiated acoustic waves carries information on the source.

34 it is piezoelectrically coupled to a surface acoustic wave cavity, realising circuit quantum acoustod

35 ng such a zero-index medium, we demonstrated acoustic wave collimation emitted from a point source.

36 It could be an acoustic wave, detected by an auditory organ as sound an

37 er-layer deposited on the surface of a shear acoustic wave device and supported a Love wave.

38 y upon specific binding on the surface of an acoustic wave device.

39 Few types of acoustic wave devices could be integrated in microfluidi

40 hese include: Bulk Acoustic Wave and Surface Acoustic Wave devices, micro- and nano-cantilever sensor

41 the responses of an array of polymer-coated acoustic wave devices.

42 g oscillations well below the frequencies of acoustic waves, down to much longer periods typical of g

43 Surface acoustic waves excited on the substrate can manipulate a

44 ieve real-time control of a standing surface acoustic wave field, which enables flexible manipulation

45 e functionalities at these frequencies, e.g. acoustic wave filtering, that are currently in widesprea

46 The scattered acoustic waves from this time-varying system experience

47 Using the acoustic waves generated in response to the absorption o

48 plying shear waves to the liver, a pneumatic acoustic wave generator was developed and tested by usin

49 rformance of guided shear horizontal surface acoustic wave (guided SH-SAW) devices on LiTaO3 substrat

50 The bulk acoustic waves in ME antennas stimulate magnetization os

51 tics concerns operations with high-frequency acoustic waves in solid media in a similar way to how tr

52 AW-based excitation generates high-frequency acoustic waves in the system relative to bulk acoustic w

53 lens capable of steering the convergence of acoustic waves in three-dimensional space.

54 itive readout, we use this to demonstrate an acoustic wave interference effect, similar to atomic coh

55 A microstructured pillar is used to couple acoustic waves into the fluid channel for noncontact par

56 The acoustic wave is focused into a small geometrical volume

57 of quartz, a temperature-compensated surface acoustic wave is generated via an interdigital transduce

58 ing unidirectional transmission property for acoustic waves is extremely desirable in many practical

59 lower part of the MT film, penetrated by the acoustic wave, is able to detect a pronounced cationic d

60 metasurface could enable a new degree of the acoustic wave manipulating and be applied in the functio

61 as versatile platforms for various advanced acoustic wave manipulation and signal modulation, leadin

62 Surface acoustic wave mediated transductions have been widely us

63 Methods of integration of the acoustic wave MEMS devices in the microfluidic systems a

64 n integrated array of polymer-coated surface acoustic wave microsensors is described.

65 single electron may be captured in a surface acoustic wave minimum and transferred from one quantum d

66 placements rules out the presence of magneto-acoustic wave modes.

67 Surface acoustic wave nebulization (SAWN) is a new technique tha

68 Surface acoustic wave nebulization (SAWN) is a novel method to t

69 anisotropies in longitudinal and transverse acoustic waves occur, especially along the [110] directi

70 ed by a Gunn diode oscillator, with coherent acoustic waves of frequency ~100 GHz, generated by pulse

71 Cell sorting by acoustic waves offers a means to separate cells on the b

72 The MARS device generates radial shear acoustic waves over a broad bandwidth that are unaffecte

73 highly efficient overlap between optical and acoustic waves over an imaging depth of >6 mm in D2O med

74 uidic channel using shear-horizontal surface acoustic waves, producing an array of virtual electrodes

75 can be detected by monitoring changes in the acoustic wave properties such as velocity, attenuation,

76 We show that acoustic waves provide a fertile ground to apply the ano

77 We study the effect of a propagating surface acoustic wave (PSAW) with different frequencies on parti

78 for numerous applications including surface acoustic wave radio frequencies devices and integrated o

79 -mean-square (RMS) phase noise by minimizing acoustic wave reflections from electrode edges, thus ena

80 on of the acoustic waveform near the surface acoustic wave resonance frequency of the levitated drop

81 Thin film bulk acoustic wave resonator (FBAR) devices supporting simult

82 aviolet (UV) light sensor based on film bulk acoustic wave resonator (FBAR) is proposed.

83 d directly by use of higher harmonics of the acoustic wave resonator and indirectly via temperature.

84 rimentally demonstrate a high-frequency bulk acoustic wave resonator that is strongly coupled to a su

85 The microchip, a commercial surface acoustic wave resonator, contains an array of interdigit

86 s and presented in this review are film bulk acoustic wave resonators (FBAR), surface acoustic waves

87 equency (f = omega/2pi) using high-frequency acoustic wave resonators.

88 thiophene) films, using thickness shear mode acoustic wave resonators.

89 s propagates through a thin metal foil as an acoustic wave, resulting in desorption of neutral molecu

90 Here we report the use of a surface acoustic wave (SAW) atomizer for fast sample handling in

91 re diagnostic device which harnesses surface acoustic wave (SAW) biochips, to detect HIV in a finger

92 ing a low-dead-volume polymer-coated surface acoustic wave (SAW) detector.

93 We describe the fabrication of a surface acoustic wave (SAW) device on a LiNbO(3) piezoelectric t

94 An 82 MHz surface acoustic wave (SAW) device was placed in contact with th

95 Surface acoustic wave (SAW) devices are widely used for signal p

96 ectra of specifically functionalized surface acoustic wave (SAW) devices concurrently with analyte ex

97 e-blood manipulation capabilities of surface acoustic wave (SAW) driven counterflow micropumps.

98 The sensor is based on a surface acoustic wave (SAW) gravimetric transducer modified with

99 We report ZnO/glass surface acoustic wave (SAW) humidity sensors with high sensitivi

100 ea alumina coatings were prepared on surface acoustic wave (SAW) mass balances.

101 ection of odorant molecules based on surface acoustic wave (SAW) resonators coated with odorant-bindi

102 ection of odorant molecules based on surface acoustic wave (SAW) resonators is presented.

103 (RESS), and deposited directly onto surface acoustic wave (SAW) resonators.

104 The use of polymer coated surface acoustic wave (SAW) sensor arrays is a very promising te

105 104 MHz lithium tantalate (LiTaO(3)) surface acoustic wave (SAW) sensor have been used to investigate

106 rs collected from six polymer-coated surface acoustic wave (SAW) sensors were used in Monte Carlo sim

107 ated using MOF-functionalized quartz surface acoustic wave (SAW) sensors.

108 f combining molecular imprinting and surface acoustic wave (SAW) technologies for the selective and l

109 energy relationships (LSERs) and the surface acoustic wave (SAW) transducers being mass sensitive.

110 Surface acoustic wave (SAW) vapor sensors with polymeric sorbent

111 trate that the propagation path of a surface acoustic wave (SAW), excited with an interdigitated tran

112 In this work, we present a surface acoustic wave (SAW)-based device that integrates a Fabry

113 uartz microcrystal balance (QMB) and surface acoustic wave (SAW).

114 e introduce highly focused traveling surface acoustic waves (SAW) at high frequencies between 193 and

115 ulk acoustic wave resonators (FBAR), surface acoustic waves (SAW) resonators and SAW delay lines.

116 We exploit the mechanical action of surface acoustic waves (SAW) to differentially lyse human cancer

117 er-billion range using an integrated surface-acoustic-wave (SAW) sensor are achieved.

118 ness-shear-mode resonator (TSMR) and surface-acoustic-wave (SAW) vapor sensors are clarified.

119 A scalable surface-acoustic-wave- (SAW-) based cantilevered device for port

120 It has recently been shown that surface acoustic waves (SAWs) can be piezoelectrically coupled t

121 In this device, two identical surface acoustic waves (SAWs) generated by interdigital transduc

122 Surface acoustic waves (SAWs) propagating on piezoelectric subst

123 Specifically, we employ surface acoustic waves (SAWs) to drive intense chaotic streaming

124 man blood plasma, using ultra-high frequency acoustic wave sensing in combination with ultrathin, oli

125 The acoustic wave sensing platform is a quartz substrate fun

126 ast gas-chromatograph coupled with a surface acoustic wave sensor (UFGC-SAW) was also used to monitor

127 notube, gold nanoparticle-based, and surface acoustic wave sensor arrays.

128 Results showed that the sensitivity of the acoustic wave sensor can be improved by simply increasin

129 sing polymer-guided shear horizontal surface acoustic wave sensor platforms on 36 degrees rotated Y-c

130 s) to amplify the mass loading effect of the acoustic wave sensor to achieve a limit of detection of

131 escribe the development and evaluation of an acoustic wave sensor, the quartz crystal microbalance (Q

132 HMF determination in honey, using a low cost acoustic wave sensor.

133 ients will not provide accurate estimates of acoustic-wave sensor responses.

134 We employed a 24-channel acoustic-wave sensor system that provided previously una

135 an array of 6 diverse polymer-coated surface acoustic wave sensors are used to illustrate the approac

136 n integrated array of polymer-coated surface acoustic wave sensors configured and tested similarly.

137 s suggest that DNA conformation probing with acoustic wave sensors is a much more improved detection

138 ity to fabricate Love wave and other surface acoustic wave sensors using planar metallization technol

139 Surface acoustic wave sensors with acoustically thin polymer fil

140 The system uses shear-horizontal surface acoustic wave (SH-SAW) sensors operating directly in the

141 es this need, using shear horizontal surface acoustic wave (SH-SAW) sensors, which function effective

142 In this study, a shear horizontal surface acoustic wave (SHSAW) was used for the detection of food

143 hich accordingly built up a standing surface acoustic wave (SSAW) field across the channel.

144 n this article, we report a standing surface acoustic wave (SSAW)-based cell coculture platform.

145 e short bursts (150 mus) of standing surface acoustic waves (SSAW) triggered by an electronic feedbac

146 into multiple outputs using standing surface acoustic waves (SSAW).

147 ng inflammatory cells using standing surface acoustic waves (SSAW).

148 nfiguration of tilted-angle standing surface acoustic waves (taSSAW), which are oriented at an optima

149 We present a versatile surface acoustic wave technique that is capable of controlling t

150 ve agreement with those obtained via surface acoustic wave techniques.

151 asic concepts remain the same: to produce an acoustic wave that can be focused at a specific location

152 to demonstrate a novel type of leaky-guided acoustic wave that couples simultaneously to two indepen

153 gh the piezo-electric effect, which produces acoustic waves that are routed and coupled to the optome

154 In this paper, we utilize bulk acoustic waves to control the position of microparticles

155 sent 3D acoustic tweezers, which use surface acoustic waves to create 3D trapping nodes for the captu

156 stage, it can also be accomplished by using acoustic waves to deflect the laser beam in a manner tha

157 The ability of surface acoustic waves to trap and manipulate micrometer-scale p

158 e we demonstrate microwave frequency surface acoustic wave transducers co-integrated with nanophotoni

159 ngle-crystal samples of periclase (MgO) from acoustic wave travel times was measured with ultrasonic

160 The precisely measured acoustic wave travel times which were used to derive the

161 particle separation via a traveling surface acoustic wave (TSAW).

162 echanical properties using traveling surface acoustic waves (TSAWs).

163 frequency separation of electromagnetic and acoustic waves using graded metasurfaces.

164 e of an array of four polymer-coated surface acoustic wave vapor sensors was explored using calibrate

165 rray of eight polymer-coated 158-MHz surface acoustic wave vapor sensors were investigated.

166 ) as models of responses from polymer-coated acoustic-wave vapor sensors are critically examined.

167 t, these ultrasonic metamaterials can convey acoustic waves with a group velocity antiparallel to pha

168 With nanoscale transducers, acoustic waves with sub-optical wavelengths can now be e