Evolution of Elastic Wave Velocities and Amplitudes During Triaxial Deformation of Aji Granite Under Dry and Water‐Saturated Conditions

Zaima, Kanta; Katayama, Ikuo

doi:10.1029/2018jb016377

Cited by 23 publications

(35 citation statements)

References 83 publications

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“…The ultrasonic voltage peak is monitored by the PVDF sensor, as shown in Fig. 2(A), which is a characteristic value of the ultrasonic field in the time domain 41 . It is found that the ultrasonic voltage peak of SFU pretreatment is higher than that of FFU pretreatment in the range 2.25–10.98%, and that of 60 ± 1 kHz/30 min with a value of 0.05387 V is the highest during the ultrasonic pretreatment process.…”

Section: Resultsmentioning

confidence: 99%

“…It is found that, with the enhancement of ultrasonic pretreatment intensity in time and frequency domains, the pectin extraction yield increases. Some studies have shown that the monitored ultrasonic signal was sensitive to changes in material properties 41 . The extraction yield is 16.70% at the strong monitored ultrasonic intensity of 0.05387 V and −6.62 dBm in the 60 ± 1 kHz/30 min pretreated group, 1.94 times higher than 5.68% at the weak ultrasonic intensity of 0.04533 V and −23.49 dBm in the 40 ± 1 kHz/15 min pretreated group, and 2 times higher than 5.55% of the control without pretreatment.…”

Section: Resultsmentioning

confidence: 99%

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Effect of ultrasonic pretreatment monitored by real‐time online technologies on dried preparation time and yield during extraction process of okra pectin

Zhang

Wang

et al. 2021

J Sci Food Agric

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BACKGROUND Ultrasonic pretreatment is a novel physical method that can be used in the extraction process of okra pectin. Real‐time online monitoring technologies were introduced in time and frequency domains when okra was pretreated. Preparation time of dried okra and yield of okra pectin were studied; and physicochemical properties of okra pectin were analyzed at the optimum ultrasonic parameter. RESULTS Results showed that ultrasonic intensity of sweeping‐frequency ultrasonic (SFU) pretreatment was stronger than that of fixed‐frequency ultrasonic pretreatment (FFU). SFU pretreatment (60 ± 1 kHz) at 30 min had a strong ultrasonic voltage peak of 0.05387 V and signal power peak of −6.62 dBm. The preparation time of dried okra was 160 ± 14.14 min in the pretreated group, 44.83% lower than control without SFU pretreatment. The intercellular space was 56.03% higher than control. Water diffusion coefficient increased from 1.41 × 10−9 to 2.14 × 10−9 m2 s−1. Monobasic quadratic equations were developed for the monitored ultrasonic intensity and pectin yield. Compared to control, extraction yield (16.70%), pectin content (0.564 mg mg−1), solubility (0.8187 g g−1) and gel strength (30.91 g) were improved in the pretreated group. Viscosity decreased, and values of G′ and G″ crossing at 63 rad s−1 revealed the viscoelastic behavior and the beginning of viscous behavior with a sol state. CONCLUSION Decrement of dried preparation time and increment of yield were achieved by ultrasonic pretreatment during the extraction process of okra pectin, and the relationship of ultrasonic intensity monitored by real‐time online technologies and yield was given. © 2021 Society of Chemical Industry

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Effect of ultrasonic pretreatment monitored by real‐time online technologies on dried preparation time and yield during extraction process of okra pectin

Zhang

Wang

et al. 2021

J Sci Food Agric

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“…Since the formation and growth of axial microcracks are characterized by dilatancy, differences in dilatant behavior between mafic and ultramafic rocks can result in the different evolutions of these physical and transport properties during deformation. In mafic rocks, marked dilation during deformation may cause a large decrease in seismic wave velocity and a large increase in permeability (e.g., Mitchell and Faulkner, 2008;Fortin et al, 2011;Zaima and Katayama, 2018). In contrast, the relatively small dilation of ultramafic rocks means that the physical and transport proper-ties of an ultramafic rock layer is not significantly modified due to the small amounts of opening of axial microcracks until failure occurs.…”

Section: Possible Influence On Physical and Transport Propertiesmentioning

confidence: 99%

Contrasting dilatant behaviors of mafic and ultramafic rocks based on triaxial deformation experiments

Akamatsu

Hatakeyama

Katayama

2019

Journal of Mineralogical and Petrological Sciences

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We performed triaxial deformation experiments on cylindrical specimens of mafic and ultramafic rocks to quantify their dilatant behaviors. Experiments were performed using an intra-vessel deformation and fluid flow apparatus at room temperature, a constant strain rate of~10 −6 s −1 , and a confining pressure of 20 MPa. Axial and radial strains were monitored using strain gauges glued to the specimens. The onset of dilatancy of mafic rocks ranged from 41 to 64% of the maximum differential stress, and the inelastic volumetric strain reached~7 × 10 −3 at the maximum differential stress. These results are generally typical of crystalline rocks. Microstructural observation of recovered samples after deformation indicates that the dilatancy of mafic rocks were caused by opening of axial microcracks. In contrast, the onset of dilatancy of ultramafic rocks occurred at >77% of the maximum differential stress, and the inelastic volumetric strain at the maximum differential stress was less than 2.7 × 10 −3. These contrasting behaviors of dilatancy could be related to different crack modes developed during deformation, where shear microcracks along grain boundary were dominated in ultramafic rocks as is evident from a nearly random crack orientation along grain boundary. As dilatancy is related to the opening of microcracks, these contrasting dilatant behaviors of mafic and ultramafic rocks can lead to different modification of the physical and transport properties during brittle deformation.

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“…Fracturing, crack opening, and saturation increase of pore fluid cause attenuation, as shown in laboratory experiments (Lockner et al 1977;Toksöz et al 1979;Tao and King 1990;Best et al 2007;Chichinina et al 2009;Amalokwu et al 2014;Zaima and Katayama 2018). These studies measured the changes in attenuation with fluid saturation and confining pressure, and reported an increase in attenuation with crack opening and saturation.…”

Section: Main Text Introductionmentioning

confidence: 86%

Temporal Change in Seismic Wave Attenuation Using High-stable Vibration Sources.

Tsuji

Yamaoka

Ikuta

2021

Preprint

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We developed a method to detect attenuation changes during seismic wave propagation excited by precisely controlled artificial seismic sources, namely Accurately Controlled Routinely Operated Signal System (ACROSS), and applied it to monitor the temporal changes for in situ data collected by previous studies. Our method, together with the use of the ACROSS sources, is less susceptible to noise level changes, from which conventional methods such as envelope calculation suffer. The method utilizes the noise level that is independently estimated in the frequency domain and eliminates the influence of the noise from the observed signal. For performance testing, we applied this method to a dataset that was obtained in an experiment at Awaji Island, Japan, from 2000 to 2001. We detected a change in amplitude caused by rainfall, variation in atmospheric temperature, and coseismic ground motions. Among them, coseismic changes are of particular interest because there are limited studies on coseismic attenuation change, in contrast to many studies on coseismic velocity decrease. At the 2000 Western Tottori earthquake (MW = 6.6, epicenter distance of 165 km), a sudden decrease in amplitude of up to 5% was observed. The coseismic amplitude reduction and its anisotropic characteristics, which showed a larger reduction in the direction of the major axis of velocity decrease, were consistent with the opening of fluid-filled cracks, as proposed by previous studies. The W corresponding to the amplitude change gives similar values to those reported in previous studies using natural earthquakes.

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Evolution of Elastic Wave Velocities and Amplitudes During Triaxial Deformation of Aji Granite Under Dry and Water‐Saturated Conditions

Cited by 23 publications

References 83 publications

Effect of ultrasonic pretreatment monitored by real‐time online technologies on dried preparation time and yield during extraction process of okra pectin

Effect of ultrasonic pretreatment monitored by real‐time online technologies on dried preparation time and yield during extraction process of okra pectin

Contrasting dilatant behaviors of mafic and ultramafic rocks based on triaxial deformation experiments

Temporal Change in Seismic Wave Attenuation Using High-stable Vibration Sources.

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