Publications
SCIE Journals
2024
[60] Nang X. Ho, Truong V. Vu*, "Liquid bridge solidification between two rods with curved caps," Chemical Engineering Science, 20244 (SCIE, IF2022 = 4.7, Q1).
[59] Nang X. Ho, Hung V. Vu, Truong V. Vu*, "Migration of a multi-core compound droplet in a ratchet microchannel," European Journal of Mechanics - B/Fluids, 2023 (SCIE, IF2019 = 2.6, Q2).
2023
[58] Nang X. Ho, Hung V. Vu, Truong V. Vu*, "Collision behaviors of two successive compound droplets in an abrupt expansion microchannel," Microgravity Science and Technology, 2023 (SCIE, IF2020=1.982, Q2+R5)
[57] Nang X Ho, Truong V Vu, "Solidification of a liquid drop enclosing a bubble on an inclined surface," European Journal of Mechanics - B/Fluids, 2023 (SCIE, IF2019 = 2.6, Q2).
[56] Hoe D Nguyen, Truong V Vu, Nang X Ho, Phan H Nguyen, Anh D Le, "Thermocapillary migration of a compound droplet on a substrate," European Journal of Mechanics - B/Fluids, 2023 (SCIE, IF2019 = 2.6, Q2).
Viet Long Doan, Ba-Quang-Vinh Nguyen , Hung T. Pham , Chi Cong Nguyen and Cuong Tien Nguyen, "Effect of time-variant NDVI on landside susceptibility: A case study in Quang Ngai province, Vietnam", Open Geosciences, 2023 (SCIE, Q2)
[55] A.D. Le, T.V. Vu, T.C. Dinh , "Cavitation Flows Past a Rotating Circular Cylinder," Journal of Fluids Engineering, 2023 (SCIE, Q2)
[54] N.X. Ho, T. V. Vu*, "Numerical study of head-on collision of two equal-sized compound droplets," Physics of Fluids, 2023 (SCIE, IF2021 = 4.980, R1+Q1)
[53] Thanh-Trung Vo, Tran Dinh Minh, Cuong T. Nguyen, T. Nguyen Nguyen, "Discrete element investigation of the mobility of granular mass flows," Solid State Communications, 2023 (SCIE, Q2)
[52] K.D. Bhagat, T. V. Vu*, et al., "Fabrication of hollow silicon millispheres through a coaxial nozzle, with observation of a novel horn structure ," Materials Today Communications, 2023 (SCIE, IF2020 = 3.662, Q2)
[51] Hoe D. Nguyen, Truong V. Vu, and Nang X. Ho*, "Impact of two successive compound droplets undergoing thermal convection ," Iranian Journal of Science and Technology, Transactions of Mechanical Engineering, 2023 (SCIE, IF2021 = 1.530 , Q2)
2022
[50] Truong V. Vu, "A numerical investigation of a liquid bridge solidifying with volume change," International Journal of Heat and Mass Transfer, 2022 (SCIE, IF2020 = 5.584, TCN+Q1)
[49]. Truong V. Vu*, and Nang X. Ho*, "Numerical study of a hollow pileup yielded by deposition of successive hollow droplets, " Physics of Fluids, 2022 (SCIE, IF2021 = 4.980, R1+Q1)
[48] Hung Vu; Truong V. Vu*; Binh Pham; Hoe Nguyen; Vinh Nguyen; Hoa Phan; Cuong Nguyen, "Deformation of a compound droplet in the wavy constricted channel," Journal of Mechanical Science and Technology, 2022 (SCIE, IF2021 = 1.81, Q2)
[47] Binh D. Pham, Truong V. Vu*, "A numerical study of a suspended compound droplet solidifying under forced convection," International Journal of Heat and Mass Transfer, Jul. 2022 (SCIE, IF2020 = 5.584, TCN+Q1)
[46] V. T. Nguyen, Truong V. Vu*, Phan H. Nguyen, Binh D. Pham, Hoe D. Nguyen, Hoa T. Phan & Hung V. Vu, "Marangoni Motion of a Droplet in a Constriction, " Microgravity Science and Technology, 2022 (SCIE, IF2020=1.982, Q1+R5)
[45] Truong V. Vu*, Hiep V. Nguyen, and Nang X. Ho*, "A numerical study of the coalescence of hollow droplets under solidification, " Physics of Fluids, 2022 (SCIE, IF2020 = 3.521, R1+Q1)
[44] Hoe D. Nguyen, Truong V. Vu*, Phan H. Nguyen, Binh D. Pham, Vinh T. Nguyen, Hung V. Vu, Cuong T. Nguyen, Duong K. Tran, "A numerical study of an impacting compound droplet undergoing thermocapillary convection" Acta Mechanica, 2022 (SCIE, IF2020 = 2.698, Q1-R2)
[43] V.T. Nguyen, Truong V. Vu*, P. Nguyen, H. Nguyen, B. Pham, H.Vu, "A Compound Droplet Undergoing Thermocapillary Migration Passing Through a Constricted Tube" Journal of Fluids Engineering, 2022 (SCIE, IF2020 = 1.995, Q2-R4)
[42] Truong V. Vu*, Binh D. Pham, Nang X. Ho, Hung V. Vu, "Solidification of a hollow sessile droplet under forced convection, " Physics of Fluids, Feb. 2022 (SCIE, IF2020 = 3.514, Q1)
2021
[41] Truong V. Vu*, Binh D. Pham, Phuc H. Pham, Hung V. Vu, and Bo X. Tran, "A numerical study of hollow water drop breakup during freezing, " Physics of Fluids, Oct. 2021 (SCIE, IF2020 = 3.514, Q1)
[40] Thanh-Trung Vo, Cuong T. Nguyen, "Characteristics of force transmission in cohesive agglomerates impacting a rigid surface," Mechanics Research Communications, Aug. 2021 (SCIE, IF2020 = 2.254, Q1).
[39] Truong V. Vu, "Three-phase solidification of a compound droplet on a curved surface," International Journal of Heat and Mass Transfer, Aug. 2021 (SCIE, IF2020 = 5.584, Q1).
[38] Dang T. Bui, Hung V. Vu, Quang D. Nguyen, Truong V. Vu*, "A multi-core compound droplet passing through a diffuser channel ", Journal of Mechanical Science and Technology, Jul. 2021 (SCIE, IF2020 = 1.734, Q2)
[37] Vinh T. Nguyen, Truong V. Vu, Phan H. Nguyen, Nang X. Ho, Binh D. Pham, Hoe D. Nguyen, Hung V. Vu, "Thermocapillary Migration of a Fluid Compound Droplet", Journal of Mechanical Science and Technology, Jun. 2021 (SCIE, IF2020 = 1.734, Q2)
[36] Thanh-Trung Vo, Cuong T. Nguyen, Trung-Kien Nguyen, Van My Nguyen, Thi Lo Vu, "Impact dynamics and power-law scaling behavior of wet agglomerates", Computational Particle Mechanics, 2021 (SCIE, IF2019 = 1.696, Q2)
[35] Binh D. Pham, Truong V. Vu, Lien V.T. Nguyen, Nang X. Ho, Cuong T. Nguyen, Hoe D. Nguyen, Vinh T. Nguyen and Hung V. Vu, “A numerical study of geometrical effects on solidification of a compound droplet on a cold flat surface,” Acta Mechanica, Jun. 2021 (SCI, IF2020 = 2.698, Q1).
[34] Cuong T. Nguyen, Hung V. Vu, Truong V. Vu, Thuan V. Truong, Nang X. Ho, Binh D. Pham, Hoe D. Nguyen, Vinh T. Nguyen, “Numerical analysis of deformation and breakup of a compound droplet in microchannels,” European Journal of Mechanics - B/Fluids, Apr. 2021 (SCI, IF2019 = 2.131, Q2).
[33] Hoe D. Nguyen, Truong V. Vu, Phan H. Nguyen, Binh D. Pham, Nang X. Ho, Cuong T. Nguyen & Vinh T. Nguyen, “Numerical study of the indentation formation of a compound droplet in a constriction,” J Mech Sci Technol, Mar. 2021 (SCIE, IF2020 = 1.734, Q2).
[32] Nang X. Ho, Truong V. Vu, Vinh T. Nguyen, Cuong T. Nguyen, and Hung V. Vu, “A numerical study of liquid compound filament contraction,” Physics of Fluids, vol. 33, no. 2, p. 023314, Feb. 2021 (SCI, IF2020 = 3.514, Q1).
2020
[31] Nang X. Ho, Truong V. Vu, Binh D. Pham, "A numerical study of a liquid compound drop solidifying on a horizontal surface," International Journal of Heat and Mass Transfer, Vol. 165, nov. 2020, pp. 120713 (SCI, IF2019 = 4.947, Q1).
[30] Nang X. Ho, Truong V. Vu, "Numerical simulation of the deformation and breakup of a two-core compound droplet in an axisymmetric T-junction channel," International Journal of Heat and Fluid Flow, Vol. 86, sept. 2020, pp. 108702 (SCI, IF2018 = 2.0, Q1).
[29] Truong V. Vu, D. T. Bui, Q. D. Nguyen, P. H. Pham, "Numerical study of rheological behaviors of a compound droplet in a conical nozzle ," International Journal of Heat and Fluid Flow, Vol. 85, Jul. 2020, pp. 108655 (SCI, IF2018 = 2.0, Q1).
[28] Khanh P. Nguyen, Truong V. Vu, "Collision Modes of Two Eccentric Compound Droplets, " Processes, vol. 8 (5), p. 602, May 2020 (SCIE, IF2018 = 1.963, Q2)
[27] Truong V. Vu, "Numerical study of solidification of a drop with a growth angle difference," International Journal of Heat and Fluid Flow, vol. 84, p. 108599 , May. 2020 (SCI, IF2018 = 2.0, Q1).
[26] Binh D. Pham, Truong V. Vu, Cuong T. Nguyen, Hoe D. Nguyen, Vinh T. Nguyen, "Numerical Study of Collision Modes of Multi-core Compound Droplets in Simple Shear Flow," Journal of Mechanical Science and Technology, Vol. 34 (5), p. 2055-2066, May 2020 (SCIE, IF2018 = 1.221, Q2).
[25] T.V. Vu, P.H. Pham, "Numerical study of a compound droplet moving toward a rigid wall in an axisymmetric channel , " International Journal of Heat and Fluid Flow , vol. 82, p. 108542, Jan. 2020 (SCI, IF2018 = 2.0, Q1).
2019
[24] K.D. Bhagat, , T.V. Vu, J.C. Wells, "Formation and Breakup of an Immiscible Compound Jet with Density or Viscosity Stratification, " Appl. Sci. 2019, 9, 4817 (SCIE, IF2018=2.217, Q1).
[23] T. V. Vu, “Parametric study of the collision modes of compound droplets in simple shear flow,” International Journal of Heat and Fluid Flow , vol. 79, p. 108470, Dec. 2019 (SCI, IF2018 = 2.0, Q1).
[22] T. V. Vu, C. T. Nguyen and Q. H. Luu, “Numerical study of a liquid drop on an inclined surface with solidification,” International Journal of Heat and Mass Transfer, vol. 144, p. 118636, Dec. 2019 (SCI, IF2018 = 4.383, Q1).
[21] T. V. Vu and Q. H. Luu, “Containerless solidification of a droplet under forced convection,” International Journal of Heat and Mass Transfer, vol. 143, p. 118498, Nov. 2019 (SCI, IF2018 = 4.383, Q1).
[20] K. D. Bhagat, T. V. Vu, J. C. Wells, H. Takakura, Y. Kawano, and F. Ogawa, “Production of hollow germanium alloy quasi-spheres through a coaxial nozzle,” Japanese Journal of Applied Physics, vol. 58, no. 6, p. 068001, May 2019 (SCI, IF2018 = 1.471, Q2).
[19] T.-V. Vu, T. V. Vu, C. T. Nguyen, and P. H. Pham, “Deformation and breakup of a double-core compound droplet in an axisymmetric channel,” Int. J. Heat Mass Transfer, vol. 135, pp. 796–810, Jun. 2019 (SCI, IF2017 = 3.891, MECHANICS: 9 of 134, Q1).
[18] T.-V. Vu, T. V. Vu, and D. T. Bui, “Numerical study of deformation and breakup of a multi-core compound droplet in simple shear flow,” Int. J. Heat Mass Transfer, vol. 131, pp. 1083–1094, Mar. 2019 (SCI, IF2017 = 3.891, MECHANICS: 9 of 134, Q1).
2018
[17] V. N. Duy and T. V. Vu, “A numerical study of a liquid drop solidifying on a vertical cold wall,” International Journal of Heat and Mass Transfer, vol. 127, pp. 302–312, Dec. 2018 (IF2017 = 3.891, MECHANICS: 9 of 134, Q1).
[16] T. V. Vu, “Axisymmetric Forced Convection Solidification of a Liquid Drop on a Cold Plate,” Int. J. Multiphase Flow, vol. 107, pp. 104–115, Jun. 2018 (IF2017 = 2.592, MECHANICS: 26 of 134, Q1).
[15] T. V. Vu, L. V. Vu, B. D. Pham, and Q. H. Luu, “Numerical investigation of dynamic behavior of a compound drop in shear flow,” J. Mech. Sci. Technol., vol. 32, no. 5, pp. 2111–2117, May 2018 (IF2016 = 1.128, ENGINEERING, MECHANICAL: 87 of 130, Q3).
[14] T. V. Vu, K. V. Dao, and B. D. Pham, “Numerical simulation of the freezing process of a water drop attached to a cold plate,” J Mech Sci Technol, vol. 32, no. 5, pp. 2119–2126, May 2018 (IF2016 = 1.128, ENGINEERING, MECHANICAL: 87 of 130, Q3).
[13] T. V. Vu, “Fully resolved simulations of drop solidification under forced convection,” Int. J. Heat Mass Transfer, vol. 122, pp. 252–263, Feb. 2018 (IF2016 = 3.458, MECHANICS: 9 of 133, Q1).
[12] T. V. Vu, “Deformation and breakup of a pendant drop with solidification,” Int. J. Heat Mass Transfer, vol. 122, pp. 341–353, Feb. 2018 (IF2016 = 3.458, MECHANICS: 9 of 133, Q1).
[11] T. V. Vu, C. T. Nguyen, and D. T. Khanh, “Direct numerical study of a molten metal drop solidifying on a cold plate with different wettability,” Metals, vol. 8, no. 1, p. 47, Jan. 2018 (IF2016 = 1.984, METALLURGY & METALLURGICAL ENGINEERING: 13 of 74, Q1).
2017
[10] T. V. Vu, “Three-phase numerical simulations of solidification with natural convection in a vertical cylindrical annulus,” Int. J. Multiphase Flow, vol. 95, pp. 120–134, Oct. 2017 (IF2016 = 2.509, MECHANICS: 27 of 133, Q1).
[9] T. V. Vu, “Three-phase computation of solidification in an open horizontal circular cylinder,” Int. J. Heat Mass Transfer, vol. 111, pp. 398–409, Aug. 2017 (IF2016 = 3.458, MECHANICS: 9 of 133, Q1).
[8] T. V. Vu and J. C. Wells, “Numerical simulations of solidification around two tandemly-arranged circular cylinders under forced convection,” Int. J. Multiphase Flow, vol. 89, pp. 331–344, Mar. 2017 (IF2015 = 2.25, MECHANICS: 23 of 135, Q1).
2016
[7] T. V. Vu, A. V. Truong, N. T. B. Hoang, and D. K. Tran, “Numerical investigations of solidification around a circular cylinder under forced convection,” J Mech Sci Technol, vol. 30, no. 11, pp. 5019–5028, Nov. 2016 (IF2015 = 0.761, ENGINEERING, MECHANICAL: 93 of 132, Q3).
[6] T. V. Vu, “Numerical simulation of inward solidification with volume change in cylindrical containers,” J. Chem. Eng. Jpn., vol. 49, no. 10, pp. 904–908, Oct. 2016 (IF2015 = 0.761, ENGINEERING, CHEMICAL: 108 of 135, Q4).
2015
[5] T. V. Vu, G. Tryggvason, S. Homma, and J. C. Wells, “Numerical investigations of drop solidification on a cold plate in the presence of volume change,” Int. J. Multiphase Flow, vol. 76, pp. 73–85, Nov. 2015 (IF2014 = 2.061, MECHANICS: 23 of 137, Q1).
2013
[4] T. V. Vu, G. Tryggvason, S. Homma, J. C. Wells, and H. Takakura, “A front-tracking method for three-phase computations of solidification with volume change,” J. Chem. Eng. Jpn., vol. 46, no. 11, pp. 726–731, Nov. 2013 (IF2012 = 0.616, ENGINEERING, CHEMICAL: 99 of 133, Q3).
[3] T. V. Vu, S. Homma, G. Tryggvason, J. C. Wells, and H. Takakura, “Computations of breakup modes in laminar compound liquid jets in a coflowing fluid,” Int. J. Multiphase Flow, vol. 49, pp. 58–69, Mar. 2013 (IF2012 = 1.175, MECHANICS: 31 of 135, Q1).
2012
[2] T. V. Vu, J. C. Wells, H. Takakura, S. Homma, and G. Tryggvason, “Numerical calculations of pattern formation of compound drops detaching from a compound jet in a co-flowing immiscible fluid,” J. Chem. Eng. Jpn., vol. 45, no. 8, pp. 721–726, Aug. 2012 (IF2011 = 0.622, ENGINEERING, CHEMICAL: 89 of 133, Q3).
2011
[1] T. V. Vu, H. Takakura, J. C. Wells, and T. Minemoto, “Breakup modes of a laminar hollow water jet,” J. Vis., vol. 14, no. 4, pp. 307–309, May 2011 (IF2011 = 0.435, COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS: 90 of 99, Q4).
Domestic Journals
[13] Bùi, Đăng T., Trần, K. D., Nguyễn, Q. Địch, & Vũ, V. T., ‘Simulation Studies and Control of Membrane Vibration in Air Sampling Pumps’, Measurement, Control, and Automation, 3(1), 10-16, 2022
[12] Binh D. Pham, Truong V. Vu, Lien V.T. Nguyen, Cuong T. Nguyen, Hoe D. Nguyen, Vinh T. Nguyen, Hung V. Vu, ‘A numerical study of the solidification process of a retracting fluid filament’, Vietnam J. Mech., Nov. 2021, doi: 10.15625/0866-7136/16393
[11] Vinh T Nguyen, Truong V Vu, Phan H Nguyen, Nang X Ho, Binh D Pham, Hoe D Nguyen, Hung V Vu, “Dynamics of a contracting fluid compound filament with a variable density ratio”, Science and Technology Development Journal., vol. 24, no. 2, May 2021.
[10] Pham Duy Binh, Vu Van Truong, Nguyen Thi Viet Lien, Nguyen Tien Cuong, Nguyen Dinh Hoe, Nguyen Tuan Vinh, Vu Van Hung, “Direct numerical simulation study of water droplets freezing on a horizontal plate”, Vietnam J. Sci. Technol., vol. 59, no. 3, Art. no. 3, May 2021, doi: 10.15625/2525-2518/59/3/15434.
[9] Vu Van Truong, Truong Viet Anh, Tran Xuan Bo, and Truong Van Thuan, “Fully resolving simulation of the phase change process of a liquid drop,” Tạp chí Khoa học và Công nghệ, Đại học Đà Nẵng, vol. 127, no. 6, 2018.
[8] V. V. Truong, “Performance Evaluation of a 2D Front Tracking Method – a Direct Numerical Simulation Method for Multiphase Flows,” Journal of Science and Technology - Technical Universities, vol. 119B, pp. 59–65, 2017.
[7] Vu Van Truong, “Numerical investigation into solidification in a horizontal annulus,” Tạp chí Khoa học và Công nghệ, Đại học Đà Nẵng, vol. 115, no. 6, pp. 30–34, 2017.
[6] V. V. Truong and T. V. Anh, “Numerical Investigation of Solidification around a Circular Cylinder with the Presence of the Free Surface in a Rectangular Cavity,” Journal of Science and Technology - Technical Universities, vol. 116, pp. 47–51, 2017.
[5] V. V. Truong, T. V. Anh, and H. T. B. Ngoc, “Numerical simulation of solidification around a circular cylinder with natural convection,” Vietnam Journal of Mechanics, vol. 38, no. 4, pp. 295–306, 2016.
[4] V. V. Truong, “Direct numerical simulation of solidification with effects of density difference,” Vietnam Journal of Mechanics, vol. 38, no. 3, pp. 193–204, 2016.
[3] Nguyễn Thế Mịch, Vũ Văn Trường, Vương Văn Quyết, and Đoàn Minh Tần, “Tính toán thiết kế tua bin Savonius phát điện có cơ cấu giảm lực cản dùng cho dòng chảy cửa sông hoặc thủy triều, phù hợp với tiềm năng dòng chảy của Việt Nam,” Tạp chí Cơ khí Việt Nam, vol. 12, pp. 45–49, 2016.
[2] Nguyễn Thế Mịch, Vũ Văn Trường, Cấn Công Thắng, and Đoàn Minh Tần, “Tính toán xác định các kích thước hình học chính các điều kiện thủy động để hệ thống tua bin dòng chảy làm việc ổn định,” Tạp chí Cơ khí Việt Nam, vol. 12, pp. 64–69, 2016.
[1] H. T. B. Ngoc and V. V. Truong, “Program for aerodynamics design of meridional contour of the multistage axial compressors,” Journal of Science and Technology - Technical Universities, vol. 66, pp. 10–15, 2008.
Non-ISI International Journals
[4] T. V. Vu, G. Tryggason, S. Homma, J. Wells, and H. Takakura, “Front tracking computation of trijunction solidification with volume change,” Procedia IUTAM, vol. 15, pp. 14–17, 2015.
[3] T. V. Vu, S. Homma, J. C. Wells, H. Takakura, and G. Tryggvason, “Numerical simulation of formation and breakup of a three-fluid compound jet,” Journal of Fluid Science and Technology, vol. 6, no. 2, pp. 252–263, 2011.
[2] T. V. Vu, H. Takakura, J. C. Wells, and T. Minemoto, “Pattern formation of hollow drops from final breakup of a hollow jet,” J. Fluid. Sci. Technol., vol. 6, no. 6, pp. 823–837, 2011.
[1] T. V. Vu, H. Takakura, J. C. Wells, and T. Minemoto, “Production of hollow spheres of eutectic tin-lead solder through a coaxial nozzle,” J. Solid Mech. Mater. Eng., vol. 4, no. 10, pp. 1530–1538, 2010.