저작자표시-비영리-변경금지 2.0 대한민국 이용자는 아래의 조건을 따르는 경우에 한하여 자유롭게 l 이 저작물을 복제, 배포, 전송, 전시, 공연 및 방송할 수 있습니다 다음과 같은 조건을 따라야 합니다: 저작자표시 귀하는 원저작자를 표시하여야 합니다 비영리 귀하는 이 저작물을 영리 목적으로 이용할 수 없습니다 변경금지 귀하는 이 저작물을 개작, 변형 또는 가공할 수 없습니다 l l 귀하는, 이 저작물의 재이용이나 배포의 경우, 이 저작물에 적용된 이용허락조건 을 명확하게 나타내어야 합니다 저작권자로부터 별도의 허가를 받으면 이러한 조건들은 적용되지 않습니다 저작권법에 따른 이용자의 권리는 위의 내용에 의하여 영향을 받지 않습니다 이것은 이용허락규약(Legal Code)을 이해하기 쉽게 요약한 것입니다 Disclaimer Ph.D Thesis Modeling and simulation of droplet dynamics for microfluidic applications Graduate School of Yeungnam University Department of Mechanical Engineering Major in Mechanical Engineering Van Thanh Hoang Advisor: Professor Jang Min Park, Ph.D August 2019 Ph.D Thesis Modeling and simulation of droplet dynamics for microfluidic applications Advisor: Professor Jang Min Park, Ph.D Presented as Ph.D Thesis August 2019 Graduate School of Yeungnam University Department of Mechanical Engineering Major in Mechanical Engineering Van Thanh Hoang ACKNOWLEDGMENTS I would like to dedicate this thesis for my late father who highly encouraged me to pursue a master and a doctoral program when he left this world almost nine years ago The thesis also is dedicated to the author’s mother who is seventy six years old and living far from me now I really would like to express my deepest gratitude to my thesis advisor, Professor Jang Min Park for dedicated help, valuable and devoted instructions, and everything he has done for me in academic direction and in my life as well over the last three years of my doctoral program I am so grateful to the committee members, Prof Jiseok Lim, Prof Jungwook Choi, Prof Kisoo Yoo, and Prof Kyoung Duck Seo for attending my presentation as well as providing pieces of advice for my doctoral thesis completion During my doctoral program, I wish to express my thanks to the Yeungnam University for supporting the scholarship and providing an excellent academic environment I also thank all of Lab members, Mr Gong Yao, Mr Liu Wankun, Mr Wu Yue, Mr Heeseung Lee, Mr Seung-Yeop Lee, always gave me encouragement and support during my doctoral program Finally, I would like to thank my family, especially my wife for their constant support and encouragement Date: May 15th, 2019 Van Thanh Hoang (호앙반탄) Multiphase Materials Processing Lab., ME/YU I ABSTRACT Design of microchannel geometry plays a key role for transport and manipulation of liquid droplets and contraction microchannel has been widely used for many applications in droplet-based microfluidic systems This study first aims to investigate droplet dynamics in contraction microchannel for more details and then to propose a simplified model used for microfluidic systems to describe droplet dynamics In particular, for contraction microchannel, three regimes of droplet dynamics, including trap, squeeze and breakup are characterized, which depends on capillary number (Ca) and contraction ratio (C) Theoretical models have been also proposed to describe transitions from one to another regime as a function of capillary number and contraction ratio The critical capillary number of transition from trap to squeeze has been found as a function of contraction ratio expressed as CaIc=a(CM-1), whereas critical capillary number CaIIc = c1C-1 depicts the transition from squeeze to breakup Additionally, the deformation, retraction and breakup along downstream of the contraction microchannel have been explored for more details To describe dynamics of droplet in microfluidic system, one-dimensional model based a Taylor analogy has been proposed to predict droplet deformation at steady state and transient behavior accurately The characteristic time for droplet reaching steady state is dependent on viscosity ratio and the droplet deformation at steady state is significantly influenced by viscosity ratio of which the order of II magnitude ranges from -1 to Finally, theoretical estimation of condition for droplet breakup was also proposed in the present study, which shows a good agreement with experimental result in the literature Keywords: Droplet dynamics, Microfluidics, Numerical simulation, Taylor analogy model III Contraction microchannel, TABLE OF CONTENTS ACKNOWLEDGMENTS .I ABSTRACT II TABLE OF CONTENTS IV LIST OF FIGURES VI NOMENCLATURES VIII CHAPTER INTRODUCTION 1.1 Droplet-based microfluidic system 1.2 Contraction microchannel in microfluidic system 1.3 Dynamics of droplet in contraction microchannel 1.4 Droplet dynamics in extensional flow 1.5 Problem statement 1.6 Dissertation overview CHAPTER PROBLEM DESCRIPTION 2.1 Problem description of contraction microchannel 2.2 Problem description for proposed model 2.3 Dimensionless numbers 11 CHAPTER TAYLOR ANALOGY MODELING 12 3.1 Damped spring-mass model 12 3.2 Taylor analogy breakup (TAB) model 13 3.3 Proposed model 15 3.4 Condition for droplet breakup 17 CHAPTER COMPUTATIONAL MODEL AND VALIDATION 18 4.1 Computational model and methods 18 4.2 Computational domain of contraction microchannel 19 4.3 Computational domain for the proposed model 22 4.4 Validation of simulation results in planar extensional flow 25 CHAPTER RESULTS AND DISCUSSIONS 27 5.1 Droplet dynamics in the contraction microchannel 27 5.1.1 Three regimes of the droplet dynamics 27 IV 5.1.2 Droplet dynamics along downstream of contraction microchannel 34 5.2 Performance of the proposed model 41 5.2.1 Steady behavior of droplet deformation 42 5.2.2 Transient behavior of droplet deformation 44 5.2.3 Critical capillary number for droplet breakup 45 CHAPTER CONSCLUSIONS AND RECOMMENDATIONS 47 6.1 Conclusions 47 6.2 Recommendations 48 REFERENCES 50 요약 59 CURRICULUM VITAE 61 V system As a result, droplet dynamics has been considered with various flow conditions of capillary number and viscosity ratio Furthermore, in order to compare with the model prediction, a board numerical simulation has been carried out to observe the droplet dynamics over a wide range of flow conditions The proposed model has been found in good agreement with the simulation results which was verified by previous experimental studies The characteristic time for droplet reaching steady state depends on viscosity ratio and the droplet deformation at steady state is significantly influenced by viscosity ratio when the order of magnitude of viscosity ratio ranges from -1 to Furthermore, theoretical estimation was developed to predict the critical capillary number for droplet breakup in the present study, which also shows an accurate prediction in compared with experimental result in the literature 6.2 Recommendations Modeling and simulation of dynamics of a droplet in microfluidic system have been studied Moreover, some recommendations for future studies are provided for more considerations of droplet dynamics in microfluidic systems - Dynamics of droplet in the contraction microchannel should be explored for its other aspects such as viscosity ratio, contact angle, the depth of microchannel, and contraction entrance geometries which have wedge-shaped or rounded shapes 48 As a results, critical capillary number for transition from one to another regime can be not only a function of contraction ratio but also a function of viscosity ratio - Effects of non-Newtonian fluid will be taken into account for a detailed rheological investigation in contraction microchannel - In the proposed model, future work can theoretically study droplet dynamics in two and three-dimensional shape based on the present proposed - Effects of elastic membrane on dynamics of droplet should be investigated in extensional/simple shear flow thanks to the present model - The proposed model can be applied for studies in chemistry, life science, and bioreactors where cells, vesicles are controlled as the droplet in this study - Effects of droplet shape on surface tension force (Equation (3.6)) are considered in Taylor analogy - Droplet dynamics can be extended to uniaxial and biaxial extensional flow 49 REFERENCES [1] J Castillo-León, W.E (Eds Svendsen, Lab-on-a-Chip Devices and MicroTotal Analysis Systems: A Practical Guide, 2015 [2] A.T Brimmo, M.A Qasaimeh, Stagnation point flows in analytical chemistry and life sciences, RSC Adv (2017) 51206–51232 [3] C.N Baroud, F Gallaire, R Dangla, Dynamics of microfluidic droplets., Lab Chip 10 (2010) 2032–2045 [4] R Seemann, M Brinkmann, T Pfohl, S Herminghaus, Droplet based microfluidics, Reports Prog Phys 75 (2012) 16601 [5] H Liu, A.J Valocchi, Y Zhang, Q Kang, Lattice Boltzmann phase-field modeling of thermocapillary flows in a confined microchannel, J Comput Phys 256 (2014) 334–356 [6] H Liu, Y Zhang, Modelling thermocapillary migration of a microfluidic droplet on a solid surface, J Comput Phys 280 (2015) 37–53 [7] S.N Oliveira, Ỉ L.E Rodd, G.H Mckinley, Ỉ M.A Alves, Simulations of extensional flow in microrheometric devices, (2008) 809–826 [8] S.L Anna, N Bontoux, H.A Stone, Formation of dispersions using “flow focusing” in microchannels, Appl Phys Lett 82 (2003) 364–366 [9] P Zhu, T Kong, L Lei, X Tian, Z Kang, Droplet Breakup in Expansioncontraction Microchannels, Nat Publ Gr (2016) 1–11 50 [10] G.C Randall, K.M Schultz, P.S Doyle, Methods to electrophoretically stretch DNA: microcontractions, gels, and hybrid gel-microcontraction devices, Lab Chip (2006) 516–525 [11] C.J Pipe, G.H McKinley, Microfluidic rheometry, Mech Res Commun 36 (2009) 110–120 [12] C Chung, M.A Hulsen, J.M Kim, K.H Ahn, S.J Lee, Numerical study on the effect of viscoelasticity on drop deformation in simple shear and 5:1:5 planar contraction/expansion microchannel, J Nonnewton Fluid Mech 155 (2008) 80–93 [13] C Chung, J.M Kim, K.H Ahn, S.J Lee, Numerical study on the effect of viscoelasticity on pressure drop and film thickness for a droplet flow in a confined microchannel, Korea-Australia Rheol J 21 (2009) 59–69 [14] C Chung, J.M Kim, M.A Hulsen, K.H Ahn, S.J Lee, Effect of viscoelasticity on drop dynamics in 5:1:5 contraction/expansion microchannel flow, Chem Eng Sci 64 (2009) 4515–4524 [15] R.E Khayat, A Luciani, L.A Utracki, Boundary-element analysis of planar drop deformation in confined flow Part Newtonian fluids, Eng Anal Bound Elem 19 (1997) 279–289 [16] R.E Khayat, A Luciani, L.A Utracki, F Godbille, J Picot, Influence of shear and elongation on drop deformation in convergent-divergent flows, Int 51 J Multiph Flow 26 (2000) 17–44 [17] A.N Christafakis, S Tsangaris, Two-Phase Flows of Droplets in Contractions and Double Bends, Eng Appl Comput Fluid Mech (2008) 299–308 [18] D.J.E Harvie, M.R Davidson, J.J Cooper-White, M Rudman, A parametric study of droplet deformation through a microfluidic contraction, ANZIAM J 46 (2005) C150–C166 [19] D.J.E Harvie, M.R Davidson, J.J Cooper-White, M Rudman, A parametric study of droplet deformation through a microfluidic contraction: Low viscosity Newtonian droplets, Chem Eng Sci 61 (2006) 5149–5158 [20] D.J.E Harvie, M.R Davidson, J.J Cooper-White, M Rudman, A parametric study of droplet deformation through a microfluidic contraction: Shear thinning liquids, Int J Multiph Flow 33 (2007) 545–556 [21] Z Zhang, J Xu, B Hong, X Chen, The effects of 3D channel geometry on CTC passing pressure - towards deformability-based cancer cell separation, Lab Chip 14 (2014) 2576–2584 [22] Z Zhang, X Chen, J Xu, Entry effects of droplet in a micro confinement: Implications for deformation-based circulating tumor cell microfiltration, Biomicrofluidics (2015) 24108 [23] M.K Mulligan, J.P Rothstein, The effect of confinement-induced shear on 52 drop deformation and breakup in microfluidic extensional flows, Phys Fluids 23 (2011) 022004 [24] M.K Mulligan, J.P Rothstein, Deformation and breakup of micro- and nanoparticle stabilized droplets in microfluidic extensional flows, Langmuir 27 (2011) 9760–9768 [25] H Chio, M.J Jensen, X Wang, H Bruus, D Attinger, Transient pressure drops of gas bubbles passing through liquid-filled microchannel contractions : an experimental study, (2006) [26] V Faustino, D Pinho, T Yaginuma, Flow of Red Blood Cells Suspensions Through Hyperbolic Microcontractions Flow of Red Blood Cells Suspensions Through Hyperbolic Microcontractions, (2014) [27] D.A.M Carvalho, A.R.O Rodrigues, V Faustino, D Pinho, E.M.S Castanheira, R Lima, Microfluidic Deformability Study of an Innovative Blood Analogue Fluid Based on Giant Unilamellar Vesicles, (2018) 1–11 [28] M.J Jensen, G Goranovi, H Bruus, The clogging pressure of bubbles in hydrophilic microchannel contractions, (2004) [29] Y.T Hu, A Lips, Determination of viscosity from drop deformation, J Rheol 45 (2001) 1453–1463 [30] M Tanyeri, E.M Johnson-Chavarria, C.M Schroeder, Hydrodynamic trap for single particles and cells., Appl Phys Lett 96 (2010) 224101 53 [31] L Guillou, J.B Dahl, J.-M.G Lin, A.I Barakat, J Husson, S.J Muller, S Kumar, Measuring Cell Viscoelastic Properties Using a Microfluidic Extensional Flow Device., Biophys J 111 (2016) 2039–2050 [32] J.B Dahl, V Narsimhan, B Gouveia, S Kumar, E.S.G Shaqfeh, S.J Muller, Experimental observation of the asymmetric instability of intermediatereduced-volume vesicles in extensional flow, Soft Matter 12 (2016) 3787– 3796 [33] Y.B Bae, H.K Jang, T.H Shin, G Phukan, T.T Tran, G Lee, W.R Hwang, J.M Kim, Microfluidic assessment of mechanical cell damage by extensional stress., Lab Chip 16 (2016) 96–103 [34] G.I Taylor, The formation of emulsions in definable fields of flow, Proc R Soc London Ser A 146 (1934) 501–523 [35] G.G Fuller, L.G Leal, Flow birefringence of concentrated polymer solutions in two-dimensional flows, J Polym Sci Polym Phys Ed 19 (1981) 557–587 [36] F.D Rumscheidt, S.G Mason, Particle motions in sheared suspensions XII Deformation and burst of fluid drops in shear and hyperbolic flow, J Colloid Sci 16 (1961) 238–261 [37] B.J Bentley, L.G Leal, An experimental investigation of drop deformation and breakup in steady, two-dimensional linear flows, J Fluid Mech 167 54 (1986) 241–283 [38] Y.T Hu, A Lips, Transient and steady state three-dimensional drop shapes and dimensions under planar extensional flow, J Rheol 47 (2003) 349–369 [39] J.-W Ha, L.G Leal, An experimental study of drop deformation and breakup in extensional flow at high capillary number, Phys Fluids 13 (2001) 1568–1576 [40] A.S Hsu, L.G Leal, Deformation of a viscoelastic drop in planar extensional flows of a Newtonian fluid, J Nonnewton Fluid Mech 160 (2009) 176–180 [41] S Ramaswamy, L.G Leal, The deformation of a viscoelastic drop subjected to steady uniaxial extensional flow of a Newtonian fluid, J Nonnewton Fluid Mech 85 (1999) 127–163 [42] N Wang, H Liu, C Zhang, Deformation and breakup of a confined droplet in shear flows with power-law rheology, J Rheol 61 (2017) 741–758 [43] H Liu, Y Ba, L Wu, Z Li, G Xi, Y Zhang, A hybrid lattice Boltzmann and finite difference method for droplet dynamics with insoluble surfactants, J Fluid Mech 837 (2018) 381–412 [44] D Yu, M Zheng, T Jin, J Wang, Asymmetric breakup of a droplet in an axisymmetric extensional flow, Chinese J Chem Eng 24 (2016) 63–70 [45] R.G Cox, The deformation of a drop in a general time-dependent fluid flow, 55 J Fluid Mech 37 (1969) 601–623 [46] D Barthès-Biesel, A Acrivos, Deformation and burst of a liquid droplet freely suspended in a linear shear field, J Fluid Mech 61 (1973) 1–22 [47] A Acrivos, T.S Lo, Deformation and breakup of a single slender drop in an extensional flow, J Fluid Mech 86 (1978) 641–672 [48] P.L Maffettone, M Minale, Equation of change for ellipsoidal drops in viscous flow, J non-Newton Fluid Mech 78 (1998) 227–241 [49] N Ioannou, H Liu, Y.H Zhang, Droplet dynamics in confinement, J Comput Sci 17 (2015) 463–474 [50] S Guido, M Villone, Three-dimensional shape of a drop under simple shear flow, J Rheol 42 (1998) 395–415 [51] M.R Kennedy, C Pozrikidis, R Skalak, Motion and deformation of liquid drops, and the rheology of dilute emulsions in simple shear flow, Comput Fluids 23 (1994) 251–278 [52] V.T Hoang, J Lim, C Byon, J.M Park, Three-dimensional simulation of droplet dynamics in planar contraction microchannel, Chem Eng Sci 176 (2018) 59–65 [53] V.T Hoang, J Min, A Taylor analogy model for droplet dynamics in planar extensional flow, Chem Eng Sci 204 (2019) 27–34 [54] G.I Taylor, The Shape and Acceleration of a Drop in a High Speed Air 56 Stream, Sci Pap Taylor G I III (1963) 457–464 [55] P.J O’Rourke, A.A Amsden, The Tab Method for Numerical Calculation of Spray Droplet Breakup, in: SAE Tech Pap., SAE International, 1987: p 872089 [56] D.G Zill, W.S Wright, Advanced Engineering Mathematics, Fifth, Jones & Bartlett Learning, 2014 [57] S Basu, B.M Cetegen, Modeling of liquid ceramic precursor droplets in a high velocity oxy-fuel flame jet, Acta Mater 56 (2008) 2750–2759 [58] F Dos Santos, L Le Moyne, Spray Atomization Models in Engine Applications, from Correlations to Direct Numerical Simulations, Oil Gas Sci Technol d’IFP Energies Nouv 66 (2011) 801–822 [59] M.R Turner, S.S Sazhin, J.J Healey, C Crua, S.B Martynov, A breakup model for transient Diesel fuel sprays, Fuel 97 (2012) 288–305 [60] K Nishad, F Ries, J Janicka, A Sadiki, Analysis of spray dynamics of urea–water-solution jets in a SCR-DeNOx system: An LES based study, Int J Heat Fluid Flow 70 (2018) 247–258 [61] I Aramendia, U Fernandez-Gamiz, A Lopez-Arraiza, C Rey-Santano, V Mielgo, F.J Basterretxea, J Sancho, M.A Gomez-Solaetxe, Experimental and numerical modeling of aerosol delivery for preterm infants, Int J Environ Res Public Health 15 (2018) 423 57 [62] C Pozrikidis, Introduction to Theoretical Computational Fluid Dynamics, Second, 2011 [63] X Bin Li, F.C Li, J.C Yang, H Kinoshita, M Oishi, M Oshima, Study on the mechanism of droplet formation in T-junction microchannel, Chem Eng Sci 69 (2012) 340–351 [64] J.U Brackbill, D.B Kothe, C Zemach, A continuum method for modeling surface tension, J Comput Phys 100 (1992) 335–354 [65] N Ioannou, H Liu, Y.H Zhang, Droplet dynamics in confinement, J Comput Sci 17 (2016) 463–474 [66] M.G Simon, R Lin, J.S Fisher, A.P Lee, A Laplace pressure based microfluidic trap for passive droplet trapping and controlled release, Biomicrofluidics (2012) 014110 [67] Fox, McDonald, Pritchard, Fundamentals of Fluid Mechanics, Eighth edi, John Wiley & Sons, Inc., 1998 [68] H.P Grace, Dispersion phenomena in high viscosity immiscible fluid systems and application of static mixers as dispersion devices in such systems, Chem Eng Commun 14 (1982) 225–277 [69] M Tjahjadi, J.M Ottino, H.A Stone, Estimating interfacial tension via relaxation of drop shapes and filament breakup, AIChE J 40 (1994) 385– 394 58 미세유체 응용을 위한 액적 동역학의 모델링 및 시뮬레이션 호앙반탄 영남대학교 대학원 기계공학과 기계공학전공 지도교수 박장민 요약 마이크로 채널 구조의 설계는 미세 유체 시스템에서 액적의 수송 및 조작에 핵심적인 역할을 하며, 수축 마이크로 채널은 액적 기반의 미세 유체 시스템에서 많은 분야에 널리 응용되고 있다 본 연구는 i) 수축 마이크로 채널에서 액적 역학을 연구하고, ii) 전체 미세 유체 시스템에 사용될 수 있는 단순화 된 액적 역학 모델을 제안하는 것을 목표로 한다 특히, 수축 마이크로 채널의 경우, 모세관 수(Ca)와 수축률(C)에 따라 트랩, 스퀴즈 및 브레이크 업의 세 가지 체제를 정량적으로 분석하였다 하나의 체제에서 다른 체제로의 전이를 기술하기위한 이론적 모델도 모세관 수와 수축률의 함수로 제안되었다 트랩에서 스퀴즈로의 전이를 설명하기 위한 중요한 모세관 수를 CaIc=a(CM-1)로 모델링 하였으며, 스퀴즈에서 해체로의 전이를 설명하기 위한 중요한 모세관 수를 CaIIc = c1C-1 로 모델링 하였다 또한, 수축 마이크로 채널의 하류를 따라 액적의 변형, 수축 및 파괴를 상세히 연구하였다 59 전체 microfluidic 시스템에서 액적의 동역학을 기술하기 위해 Taylor analogy 를 기반으로 한 차원 모델을 제안하였다 정상 상태에 도달하는 액적 거동의 특성 시간은 액적과 주변 유체의 점도 비율에 의존적임을 확인하였으며, 정상 상태에서의 액적 변형은 점도 비율의 크기 정도가 -1 에서 까지의 구간에서 가장 크게 영향을 받음을 확인하였다 마지막으로, 액적 분열 예측을 위한 이론적인 모델이 제안되었다 본 연구에서 제안된 모델의 예측값은 기존 연구의 실험 결과와 일치함을 확인하였다 Keywords : Droplet dynamics, Microfluidics, 수축 마이크로 채널, 수치 해석, Taylor analogy model 60 CURRICULUM VITAE HOANG VAN THANH (호앙반탄) Nationality: Vietnamese Email: hvthanh@dut.udn.vn Education: 2016.03-present: Ph.D candidate - School of Mechanical Engineering, Yeungnam University (YU), Republic of Korea 2010.02-2012.01: M.S - Department of Mechanical Engineering, National Taiwan University of Science and Technology (NTUST), Taiwan 2003.09-2008.06: B.S - Department of Mechanical Engineering, Danang University of Science and Technology, The University of Danang, Vietnam Publications in the Ph.D Program: Journal Van Thanh Hoang, Chan Byon, Jiseok Lim* and Jang Min Park*, Threedimensional simulation of droplet dynamics in planar contraction microchannel, Chemical Engineering Science, (2018) 176, 59-65 Van Thanh Hoang and Jang Min Park*, A Taylor analogy model for droplet dynamics in planar extensional flow, Chemical Engineering Science, (2019) 204, 27-34 Conference Van Thanh Hoang, Chan Byon, Jiseok Lim and Jang Min Park, Study on droplet dynamics through microfluidic contraction, Annual Conference of Vietnamese Young Scientists, Korea, 2017 Van Thanh Hoang, Quang Bang Tao, Duc Binh Luu, Jang Min Park*, Dynamics of a droplet at trap-squeeze transition in contraction microchannel, 17th International Symposium on Advanced Technology (ISAT-17), 2018 Previous publications: Hoang Van Thanh, Chao-Chang A Chen, Chia-Hsing Kuo, Injection molding of PC/PMMA Blend for Fabricate of the Secondary Optical Elements of LED Illumination, Advanced Materials Research, Trans Tech Publications, Switzerland, (2012), 579, 134-141 Hoang Van Thanh, Chao-Chang A Chen, Chia-Hsing Kuo, Experimental Study of Mechanical Properties of PC/PMMA blends by Injection Molding Process, The 4th International Conference on Advanced Manufacturing, ICAM (2012), 63-67 61 Van Thanh Hoang, Duc Binh Luu, Study on student engagement levels to class activities, VEEC 2015 Hoang Van Thanh, Injection Molding Technology of Optical Elements in LED Illumination, LAP LAMBERT Academic Publishing, eBook, (2013), https://www.amazon.com/Injection-Molding-Technology-ElementsIllumination/dp/3844392394 62 ...Ph.D Thesis Modeling and simulation of droplet dynamics for microfluidic applications Graduate School of Yeungnam University Department of Mechanical Engineering Major in... Van Thanh Hoang Advisor: Professor Jang Min Park, Ph.D August 2019 Ph.D Thesis Modeling and simulation of droplet dynamics for microfluidic applications Advisor: Professor Jang Min Park, Ph.D... three-dimensional numerical simulation and theoretical modeling In droplet- based microfluidic systems, dynamics of droplet in microfluidic systems is determined by the strength of the flow type which