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      KCI등재 SCIE SCOPUS

      Particle trajectory and orientation evolution of ellipsoidal particles in bounded shear flow of Giesekus fluids

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      https://www.riss.kr/link?id=A107918882

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      다국어 초록 (Multilingual Abstract)

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      The migration of ellipsoidal particles in bounded shear flow of Giesekus fluids is studied numerically using the direct forcing/fictitious domain method for the Weissenberg number ranging from 0.1 to 3.0, the mobility parameter α which quantifies the shear-thinning effect ranging from 0.1 to 0.7. The model and numerical method are validated by comparing the present results with available theoretical and numerical results in other literatures. The results show that the trajectory of particles depends on their initial orientation and vertical position, and the particle migration can be roughly classified into returning and passing pattern. The values of initial vertical position of particle corresponding to the separatrix between the returning and passing pattern decrease with increasing Weissenberg number regardless of the initial orientation of particle, and the shear thinning has the opposite effect. The evolution of particle orientation depends on the initial particle orientation. For the particles whose initial orientation is parallel to the shear plane, the particle rotates with the semi-major axis as radius in the shear plane. For the particles whose initial orientation is perpendicular to the shear plane, the particle rotates with the semi-minor axis as radius. For the particles whose initial orientation has a certain angle with the shear plane, the particle rotates with the vorticity axis and the orientation vector is gradually close to the vorticity vector. The evolution of the particle orientation becomes slow with increasing Wi whether it is in passing behavior or in returning behavior.
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      The migration of ellipsoidal particles in bounded shear flow of Giesekus fluids is studied numerically using the direct forcing/fictitious domain method for the Weissenberg number ranging from 0.1 to 3.0, the mobility parameter α which quantifies the...

      The migration of ellipsoidal particles in bounded shear flow of Giesekus fluids is studied numerically using the direct forcing/fictitious domain method for the Weissenberg number ranging from 0.1 to 3.0, the mobility parameter α which quantifies the shear-thinning effect ranging from 0.1 to 0.7. The model and numerical method are validated by comparing the present results with available theoretical and numerical results in other literatures. The results show that the trajectory of particles depends on their initial orientation and vertical position, and the particle migration can be roughly classified into returning and passing pattern. The values of initial vertical position of particle corresponding to the separatrix between the returning and passing pattern decrease with increasing Weissenberg number regardless of the initial orientation of particle, and the shear thinning has the opposite effect. The evolution of particle orientation depends on the initial particle orientation. For the particles whose initial orientation is parallel to the shear plane, the particle rotates with the semi-major axis as radius in the shear plane. For the particles whose initial orientation is perpendicular to the shear plane, the particle rotates with the semi-minor axis as radius. For the particles whose initial orientation has a certain angle with the shear plane, the particle rotates with the vorticity axis and the orientation vector is gradually close to the vorticity vector. The evolution of the particle orientation becomes slow with increasing Wi whether it is in passing behavior or in returning behavior.

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      참고문헌 (Reference)

      1 Warkiani, M. E., "Ultra-fast, labelfree isolation of circulating tumor cells from blood using spiral microfluidics" 11 : 134.13-, 2016

      2 Yoon, S., "Two particle interactions in a confined viscoelastic fluid under shear" 185-186 : 39-48, 2012

      3 Jeffery, G. B., "The motion of ellipsoidal particles immersed in a viscous fluid" 102 : 161-179, 1922

      4 Rapaport, D. C., "The Art of Molecular Dynamics Simulation" Cambridge University Press 1995

      5 Vazquez-Quesada, A., "SPH modeling and simulation of spherical particles interacting in a viscoelastic matrix" 29 : 121609-, 2017

      6 D’Avino, G., "Rheology of a dilute viscoelastic suspension of spheroids in unconfined shear flow" 54 : 915-928, 2015

      7 Anczurowski, E., "Particle motions in sheared suspensions. XXIV. Rotation of rigid spheroids and cylinders" 12 : 209-, 1968

      8 Liu, B., "Particle migration in bounded shear flow of Giesekus fluids" 276 : 104233-, 2020

      9 D’Avino, G., "Particle migration due to viscoelasticity of the suspending liquid and its relevance in microfluidic devices" 49 : 341-360, 2017

      10 D’Avino, G., "Particle dynamics in viscoelastic liquids" 215 : 80-104, 2015

      1 Warkiani, M. E., "Ultra-fast, labelfree isolation of circulating tumor cells from blood using spiral microfluidics" 11 : 134.13-, 2016

      2 Yoon, S., "Two particle interactions in a confined viscoelastic fluid under shear" 185-186 : 39-48, 2012

      3 Jeffery, G. B., "The motion of ellipsoidal particles immersed in a viscous fluid" 102 : 161-179, 1922

      4 Rapaport, D. C., "The Art of Molecular Dynamics Simulation" Cambridge University Press 1995

      5 Vazquez-Quesada, A., "SPH modeling and simulation of spherical particles interacting in a viscoelastic matrix" 29 : 121609-, 2017

      6 D’Avino, G., "Rheology of a dilute viscoelastic suspension of spheroids in unconfined shear flow" 54 : 915-928, 2015

      7 Anczurowski, E., "Particle motions in sheared suspensions. XXIV. Rotation of rigid spheroids and cylinders" 12 : 209-, 1968

      8 Liu, B., "Particle migration in bounded shear flow of Giesekus fluids" 276 : 104233-, 2020

      9 D’Avino, G., "Particle migration due to viscoelasticity of the suspending liquid and its relevance in microfluidic devices" 49 : 341-360, 2017

      10 D’Avino, G., "Particle dynamics in viscoelastic liquids" 215 : 80-104, 2015

      11 Mutlu, B. R., "Oscillatory inertial focusing in infinite microchannels" 115 : 7682-7687, 2018

      12 Wang, Y., "Numerical simulations of the motion of ellipsoids in planar Couette flow of Giesekus viscoelastic fluids" 23 : 89-, 2019

      13 Mutlu, B. R., "Non-equilibrium inertial separation array for high throughput" 7 : 9915-, 2017

      14 Crowe, C. T., "Multiphase Flows with Droplets and Particles" CRC Press 2011

      15 Warkiani, M. E., "Membrane-less microfiltration using inertial microfluidics" 5 : 11018-, 2015

      16 Kang, A. R., "Medium viscoelastic effect on particle segregation in concentrated suspensions under rectangular microchannel flows" 23 : 247-254, 2011

      17 Snijkers, F., "Hydrodynamic interactions between two equally sized spheres in viscoelastic fluids in shear flow" 29 : 5701-5713, 2013

      18 김성현, "Effect of partiicle migration on the heat transfer of nanofluid" 한국유변학회 19 (19): 99-107, 2007

      19 D’Avino, G., "Bistability and metabistability scenario in the dynamics of an ellipsoidal particle in a sheared viscoelastic fluid" 89 : 043006-, 2014

      20 Choi, Y. J., "An extended finite element method for the simulation of particulate viscoelastic flows" 165 : 607-624, 2010

      21 Jungmi Yoo, "Alignment of spherical particles in rheologically complex fluid under torsional flow" Springer Science and Business Media LLC 26 (26): 177-183, 2014

      22 Wang, X., "A low-cost, plug-andplay inertial microfluidic helical capillary device for highthroughput flow cytometry" 11 : 014107-, 2017

      23 Yu, Z., "A fictitious domain method for dynamic simulation of particle sedimentation in Bingham fluids" 145 : 78-91, 2007

      24 Yu, Z., "A direct-forcing fictitious domain method for particulate flows" 227 : 292-314, 2007

      25 Pan, T. W., "A 3D DLM/FD method for simulating the motion of spheres and ellipsoids under creeping flow conditions" 352 : 410-425, 2018

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      학술지 이력

      학술지 이력
      연월일 이력구분 이력상세 등재구분
      2023 평가예정 해외DB학술지평가 신청대상 (해외등재 학술지 평가)
      2020-01-01 평가 등재학술지 유지 (해외등재 학술지 평가) KCI등재
      2012-01-01 평가 SCIE 등재 (등재유지) KCI등재
      2012-01-01 평가 SCOPUS 등재 (등재유지) KCI등재
      2011-01-01 평가 등재후보학술지 유지 (등재후보2차) KCI등재후보
      2010-01-01 평가 등재후보 1차 PASS (등재후보1차) KCI등재후보
      2003-01-01 평가 SCIE 등재 (신규평가) KCI등재후보
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      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 1.01 0.18 0.77
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.59 0.52 0.327 0.06
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