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Journal articles on the topic 'Physical flows'

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Published: 4 June 2021
Last updated: 5 February 2022

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1

Palmisano, Liviana. "On physical measures for Cherry flows." Fundamenta Mathematicae 232, no. 2 (2016): 167–79. http://dx.doi.org/10.4064/fm232-2-5.

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2

Wang, Chengwei, Celso Grebogi, and Murilo S. Baptista. "Uncovering hidden flows in physical networks." EPL (Europhysics Letters) 118, no. 5 (2017): 58001. http://dx.doi.org/10.1209/0295-5075/118/58001.

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3

Glatt, Moritz, and Jan C. Aurich. "Physical modeling of material flows in cyber-physical production systems." Procedia Manufacturing 28 (2019): 10–17. http://dx.doi.org/10.1016/j.promfg.2018.12.003.

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4

Benim, A. C., and M. P. Escudier. "Turbulent Swirling Flows: Physical Phenomena and Modelling." Computational Technology Reviews 1 (September 14, 2010): 215–50. http://dx.doi.org/10.4203/ctr.1.8.

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5

Fannin, R. J., and T. P. Rollerson. "Debris flows: some physical characteristics and behaviour." Canadian Geotechnical Journal 30, no. 1 (1993): 71–81. http://dx.doi.org/10.1139/t93-007.

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Field observations on 449 debris flows in the Queen Charlotte Islands, British Columbia, are summarized. Movement of debris is classified according to seven characteristic types designated for the purposes of the study. Data on the physical characteristics of the events are presented. An analysis of the data is made with reference to event initiation, yield, and deposition using both mechanistic and morphological criteria. For those events which initiate on an open slope, the infinite slope model is used to establish a relationship between field drainage class and slope angle, for assumed fric
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6

Saghin, Radu, Wenxiang Sun, and Edson Vargas. "On Dirac Physical Measures for Transitive Flows." Communications in Mathematical Physics 298, no. 3 (2010): 741–56. http://dx.doi.org/10.1007/s00220-010-1077-9.

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7

Su, Hongbo, Sudhagar Nagarajan, and Jinwei Dong. "Physical and Economic Processes of Ecosystem Services Flows." Physics and Chemistry of the Earth, Parts A/B/C 101 (October 2017): 1–2. http://dx.doi.org/10.1016/j.pce.2017.10.001.

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8

Malanchev, Konstantin L., Konstantin A. Postnov, and Nikolay I. Shakura. "Physical conditions in thin laminar-convective accretion flows." Journal of Physics: Conference Series 1390 (November 2019): 012085. http://dx.doi.org/10.1088/1742-6596/1390/1/012085.

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9

Borisoglebskaya, L. N., O. Ja Kravets, O. V. Pilipenko, and V. V. Provotorov. "Cyber-physical control system for integrated material flows." Journal of Physics: Conference Series 1399 (December 2019): 044044. http://dx.doi.org/10.1088/1742-6596/1399/4/044044.

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10

Sullivan, P. J. "Physical modeling of contaminant diffusion in environmental flows." Environmetrics 1, no. 2 (2007): 163–77. http://dx.doi.org/10.1002/env.3170010204.

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11

Singh, H. P., D. D. Tripathi, and R. B. Mishra. "Physical study of steady electromagnetofluid-dynamic viscous flows." Computers & Mathematics with Applications 15, no. 3 (1988): 161–68. http://dx.doi.org/10.1016/0898-1221(88)90167-8.

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12

Huang, Biao, GuoYu Wang, Yu Zhao, and Qin Wu. "Physical and numerical investigation on transient cavitating flows." Science China Technological Sciences 56, no. 9 (2013): 2207–18. http://dx.doi.org/10.1007/s11431-013-5315-1.

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13

YANG, JIAGANG. "Cherry flow: physical measures and perturbation theory." Ergodic Theory and Dynamical Systems 37, no. 8 (2016): 2671–88. http://dx.doi.org/10.1017/etds.2016.13.

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In this article we consider Cherry flows on the torus which have two singularities, a source and a saddle, and no periodic orbits. We show that every Cherry flow admits a unique physical measure, whose basin has full volume. This proves a conjecture given by Saghin and Vargas [Invariant measures for Cherry flows.Comm. Math. Phys.317(1) (2013), 55–67]. We also show that the perturbation of Cherry flows depends on the divergence at the saddle: when the divergence is negative, this flow admits a neighborhood, such that any flow in this neighborhood belongs to one of the following three cases: it
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14

Drake, Thomas G. "Granular flow: physical experiments and their implications for microstructural theories." Journal of Fluid Mechanics 225 (April 1991): 121–52. http://dx.doi.org/10.1017/s0022112091001994.

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Positions, velocities and rotations of individual particles obtained from high-speed motion pictures of essentially two-dimensional flows of plastic spheres in an inclined glass-walled chute were used to test critical assumptions of microstructural theories for the flow of granular materials. The measurements provide a well-defined set of observations for refining and validating computer simulations of granular flows, and point out some important limitations of physical experiments. Two nearly steady, uniform, collisional flows of 6-mm-diameter plastic spheres over a fixed bed of similar spher
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15

Marenduzzo, D., E. Orlandini, and J. M. Yeomans. "Permeative flows in cholesterics: Shear and Poiseuille flows." Journal of Chemical Physics 124, no. 20 (2006): 204906. http://dx.doi.org/10.1063/1.2198816.

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16

Ferrari, Attilio, and Edoardo Trussoni. "Wind-type flows in quasars." Symposium - International Astronomical Union 119 (1986): 399–403. http://dx.doi.org/10.1017/s0074180900153069.

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Jets are found in many astrophysical phenomena, from young stellar objects and collapsed stellar cores to quasar and radiogalaxies. Therefore they must represent a common dynamical phenomenon, while different morphological characteristics arise from the interaction with specific environments (Ferrari and Tsinganos 1985). In order to investigate the basic aspects of jet dynamics and morphologies, we have proposed a simple analytical treatment based on the fluid theory of stellar winds (Parker, 1063), which allows a direct test of different physical effects (Ferrari et al. 1985, 1986). We discus
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17

LI, Jun, and Wen CHEN. "Physical Layer Network Coding for Wireless Cooperative Multicast Flows." IEICE Transactions on Communications E92-B, no. 8 (2009): 2559–67. http://dx.doi.org/10.1587/transcom.e92.b.2559.

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18

Chefrakov, S. G. "Numerical and physical aspects of research on aerodynamic flows." Uspekhi Fizicheskih Nauk 156, no. 11 (1988): 553. http://dx.doi.org/10.3367/ufnr.0156.198811j.0553.

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19

Ledukhovsky, G. V., V. P. Zhukov, and E. V. Barochkin. "Regularization of physical gas flows in complex power systems." Vestnik IGEU, no. 6 (2016): 5–15. http://dx.doi.org/10.17588/2072-2672.2016.6.005-015.

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20

RUBIDO, NICOLÁS, CELSO GREBOGI, and MURILO S. BAPTISTA. "Interpreting physical flows in networks as a communication system." Indian Academy of Sciences – Conference Series 1, no. 1 (2017): 17–23. http://dx.doi.org/10.29195/iascs.01.01.0016.

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21

Chefranov, S. G. "Numerical and physical aspects of research on aerodynamic flows." Soviet Physics Uspekhi 31, no. 11 (1988): 1041–42. http://dx.doi.org/10.1070/pu1988v031n11abeh005657.

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22

Fernandez, Victor M., Deborah Silver, Norman J. Zabusky, and Steve Bryson. "Visiometrics of Complex Physical Processes: Diagnosing Vortex-Dominated Flows." Computers in Physics 10, no. 5 (1996): 463. http://dx.doi.org/10.1063/1.4822474.

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23

Gollin, D., E. Bowman, and P. Shepley. "Methods for the physical measurement of collisional particle flows." IOP Conference Series: Earth and Environmental Science 26 (September 9, 2015): 012017. http://dx.doi.org/10.1088/1755-1315/26/1/012017.

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24

Boufadel, Michel C., Makram T. Suidan, Albert D. Venosa, Christian H. Rauch, and Pratim Biswas. "2D Variably Saturated Flows: Physical Scaling and Bayesian Estimation." Journal of Hydrologic Engineering 3, no. 4 (1998): 223–31. http://dx.doi.org/10.1061/(asce)1084-0699(1998)3:4(223).

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25

Chen, T. R., G. Y. Wang, B. Huang, D. Q. Li, X. J. Ma, and X. L. Li. "Effects of physical properties on thermo-fluids cavitating flows." Journal of Physics: Conference Series 656 (December 3, 2015): 012181. http://dx.doi.org/10.1088/1742-6596/656/1/012181.

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26

Muste, Marian, Ehab A. Meselhe, Larry J. Weber, and Allen A. Bradley. "Coupled physical-numerical analysis of flows in natural waterways." Journal of Hydraulic Research 39, no. 1 (2001): 51–60. http://dx.doi.org/10.1080/00221680109499802.

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27

Argyris, John, Ioannis St Doltsinis, Heinz Friz, and Jürgen Urban. "Physical and computational aspects of chemically reacting hypersonic flows." Computer Methods in Applied Mechanics and Engineering 111, no. 1-2 (1994): 1–35. http://dx.doi.org/10.1016/0045-7825(94)90038-8.

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28

Bally, John, and David Devine. "Giant Herbig-Haro Flows." Symposium - International Astronomical Union 182 (1997): 29–38. http://dx.doi.org/10.1017/s0074180900061519.

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Recent observations with wide field-of-view CCDs have shown that over 20 Herbig-Haro flows extend for more than one parsec from their driving sources. We review the observed properties of these giant HH flows and discuss the physical consequences for star formation, and for the physics and chemistry of the surrounding interstellar medium.
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29

Groves, D. A., R. L. Morton, and J. M. Franklin. "Physical volcanology of the footwall rocks near the Mattabi massive sulphide deposit, Sturgeon Lake, Ontario." Canadian Journal of Earth Sciences 25, no. 2 (1988): 280–91. http://dx.doi.org/10.1139/e88-030.

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Subaerial and shallow subaqueous mafic hyalotuffs, lava flows, and flow breccias, felsic lava flows, and pyroclastic flows and falls form a 2 km thick succession beneath the Mattabi massive sulphide deposit. The lowermost 800 m of section comprises massive to amygdaloidal mafic flows and flow breccias interlayered with repetitive sequences of thinly bedded felsic tuff: pillow lavas and hyaloclastites are absent. Amygdaloidal felsic lavas overlie the mafic flows and are locally capped by coarse explosion breccia. This breccia is believed to represent the start of mafic hydrovolcanism, which pro
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30

Woodward, J. R., J. W. Pitchford, and M. A. Bees. "Physical flow effects can dictate plankton population dynamics." Journal of The Royal Society Interface 16, no. 157 (2019): 20190247. http://dx.doi.org/10.1098/rsif.2019.0247.

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Oceanic flows do not necessarily mix planktonic species. Differences in individual organisms’ physical and hydrodynamic properties can cause changes in drift normal to the mean flow, leading to segregation between species. This physically driven heterogeneity may have important consequences at the scale of population dynamics. Here, we describe how one form of physical forcing, circulating flows with different inertia effects between phytoplankton and zooplankton, can dramatically alter excitable plankton bloom dynamics. This may impact our understanding of the initiation and development of ha
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31

Wong, Chong Yau, Joan Boulanger, and Gregory Short. "Modelling the Effect of Particle Size Distribution in Multiphase Flows with Computational Fluid Dynamics and Physical Erosion Experiments." Advanced Materials Research 891-892 (March 2014): 1615–20. http://dx.doi.org/10.4028/www.scientific.net/amr.891-892.1615.

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It is known that particle size has an influence in determining the erosion rate, and hence equipment life, on a target material in single phase flows (i.e. flow of solid particles in liquid only or gas only flows). In reality single phase flow is rarely the case for field applications in the oil and gas industry. Field cases are typically multiphase in nature, with volumetric combinations of gas, liquid and sand. Erosion predictions of multiphase flows extrapolated from single phase flow results may be overly conservative. Current understanding of particle size distribution on material erosion
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32

Iliopoulou, Theano, Cristina Aguilar, Berit Arheimer, et al. "A large sample analysis of European rivers on seasonal river flow correlation and its physical drivers." Hydrology and Earth System Sciences 23, no. 1 (2019): 73–91. http://dx.doi.org/10.5194/hess-23-73-2019.

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Abstract. The geophysical and hydrological processes governing river flow formation exhibit persistence at several timescales, which may manifest itself with the presence of positive seasonal correlation of streamflow at several different time lags. We investigate here how persistence propagates along subsequent seasons and affects low and high flows. We define the high-flow season (HFS) and the low-flow season (LFS) as the 3-month and the 1-month periods which usually exhibit the higher and lower river flows, respectively. A dataset of 224 rivers from six European countries spanning more than
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33

Fasel, Hermann F., Dominic A. von Terzi, and Richard D. Sandberg. "A Methodology for Simulating Compressible Turbulent Flows." Journal of Applied Mechanics 73, no. 3 (2005): 405–12. http://dx.doi.org/10.1115/1.2150231.

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A flow simulation Methodology (FSM) is presented for computing the time-dependent behavior of complex compressible turbulent flows. The development of FSM was initiated in close collaboration with C. Speziale (then at Boston University). The objective of FSM is to provide the proper amount of turbulence modeling for the unresolved scales while directly computing the largest scales. The strategy is implemented by using state-of-the-art turbulence models (as developed for Reynolds averaged Navier-Stokes (RANS)) and scaling of the model terms with a “contribution function.” The contribution funct
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34

Cao, Lingling, Yannan Wang, Qing Liu, and Xiaoming Feng. "Physical and Mathematical Modeling of Multiphase Flows in a Converter." ISIJ International 58, no. 4 (2018): 573–84. http://dx.doi.org/10.2355/isijinternational.isijint-2017-680.

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35

Pfister, Michael, and Hubert Chanson. "Two-phase air-water flows: Scale effects in physical modeling." Journal of Hydrodynamics 26, no. 2 (2014): 291–98. http://dx.doi.org/10.1016/s1001-6058(14)60032-9.

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36

Shojaie, A., and M. Safaeinezhad. "Physical simulation for mobile nanorobot in the bloody laminar flows." Journal of Biomechanics 39 (January 2006): S446. http://dx.doi.org/10.1016/s0021-9290(06)84822-0.

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37

Cetin, Mecit, and George F. List. "Integrated modeling of information and physical flows in transportation systems." Transportation Research Part C: Emerging Technologies 14, no. 2 (2006): 139–56. http://dx.doi.org/10.1016/j.trc.2006.06.003.

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38

Wu, Pute, La Zhuo, Yilin Liu, et al. "Assessment of regional crop-related physical-virtual water coupling flows." Chinese Science Bulletin 64, no. 18 (2019): 1953–66. http://dx.doi.org/10.1360/n972018-00997.

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39

Cantero-Chinchilla, Francisco Nicolás, Oscar Castro-Orgaz, Subhasish Dey, and Jose Luis Ayuso. "Nonhydrostatic Dam Break Flows. I: Physical Equations and Numerical Schemes." Journal of Hydraulic Engineering 142, no. 12 (2016): 04016068. http://dx.doi.org/10.1061/(asce)hy.1943-7900.0001205.

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40

Ferland, G. J., A. C. Fabian, and R. M. Johnstone. "The physical conditions within dense cold clouds in cooling flows." Monthly Notices of the Royal Astronomical Society 266, no. 2 (1994): 399–411. http://dx.doi.org/10.1093/mnras/266.2.399.

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41

Többen, Johannes. "On the simultaneous estimation of physical and monetary commodity flows." Economic Systems Research 29, no. 1 (2017): 1–24. http://dx.doi.org/10.1080/09535314.2016.1271774.

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42

Pechatnikov, Yu M. "Engineering physical model of gas flows in a medium vacuum." Technical Physics 48, no. 8 (2003): 978–82. http://dx.doi.org/10.1134/1.1608558.

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43

Zhang, Shuai, Limin Zhang, Xueyou Li, and Qiang Xu. "Physical vulnerability models for assessing building damage by debris flows." Engineering Geology 247 (December 2018): 145–58. http://dx.doi.org/10.1016/j.enggeo.2018.10.017.

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44

Bollada, P. C., and T. N. Phillips. "A physical decomposition of the stress tensor for complex flows." Rheologica Acta 47, no. 7 (2008): 719–25. http://dx.doi.org/10.1007/s00397-007-0256-x.

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45

Faure, Sylvain, and Jean-Michel Ghidaglia. "Violent flows in aqueous foams I: Physical and numerical models." European Journal of Mechanics - B/Fluids 30, no. 4 (2011): 341–59. http://dx.doi.org/10.1016/j.euromechflu.2011.03.003.

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46

Mi, Zeya. "Physical measures for partially hyperbolic flows with mostly contracting centre." Dynamical Systems 36, no. 3 (2021): 427–44. http://dx.doi.org/10.1080/14689367.2021.1927988.

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47

Ingham, D. B., A. K. Al-Hadhrami, L. Elliott, and X. Wen. "Fluid Flows Through Some Geological Discontinuities." Journal of Applied Mechanics 73, no. 1 (2005): 34–40. http://dx.doi.org/10.1115/1.1991861.

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In this paper the fluid flow through some composite channels has been investigated in the physical parameter ranges appropriate to some flows in geological applications. In particular, we have considered the fluid flow through a composite channel that has undergone a vertical fracture. The vertical connecting channel is also composed of a composite material. In such physical situations, the materials undergo several orders of magnitude changes in their Darcy numbers. This results in very large changes in the pressure in the vicinity of the interfaces between these materials. Therefore it is ne
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48

TAN, BAI-HE, and ZI-NIU WU. "FLUX SPIKES IN VISCOUS FLOWS." Mathematical Models and Methods in Applied Sciences 14, no. 01 (2004): 143–63. http://dx.doi.org/10.1142/s0218202504003180.

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In this paper we will study the condition for the occurrence of flux spikes, such as momentum spikes for the Navier–Stokes equations. Flux spikes are observed in Computational Fluid Dynamics, but it is unknown what are the exact conditions at which they occur and whether they are physical or purely numerical. In the present paper we try to clarify these questions.
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49

HUNG, TIN-KAN. "VORTICES IN BIOLOGICAL FLOWS." Journal of Mechanics in Medicine and Biology 13, no. 05 (2013): 1340001. http://dx.doi.org/10.1142/s0219519413400010.

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Vortices in flow past a heart valve, in streams and behind an arrow were realized, sketched and discussed by Leonardo da Vinci. The forced resonance and collapse of the Tacoma Narrows Bridge under 64 km/h. wind in 1940 and the Kármán vortex street are classic examples of dynamic interaction between fluid flow and solid motion. There are similar and dissimilar characteristics of vortices between biological and physical flow processes. They can be analyzed by numerical solutions of the Navier–Stokes equations with moving boundaries. One approach is to transform the time-dependent domain to a fix
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50

Brandner, Paul A., James A. Venning, and Bryce W. Pearce. "Wavelet analysis techniques in cavitating flows." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 376, no. 2126 (2018): 20170242. http://dx.doi.org/10.1098/rsta.2017.0242.

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Cavitating and bubbly flows involve a host of physical phenomena and processes ranging from nucleation, surface and interfacial effects, mass transfer via diffusion and phase change to macroscopic flow physics involving bubble dynamics, turbulent flow interactions and two-phase compressible effects. The complex physics that result from these phenomena and their interactions make for flows that are difficult to investigate and analyse. From an experimental perspective, evolving sensing technology and data processing provide opportunities for gaining new insight and understanding of these comple
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