IUPUI School of Engineering and Technology

Publications

Computational Modeling and Simulation
1. X. Zhang, J. McDonough, and H. Yu*, Laminar and Turbulent Behavior Captured by A 3-D Kinetic-Based Discrete Dynamic System, in “Proceedings of the Eleventh International Conference on Computational Fluid Dynamics (ICCFD11)”, Maui, HI, USA, July 11-15, 2022. (PDF)
2. H. Li, M. Islam, H. Yu*, and X. Du, Physics-Based Regression vs. CFD for Hagen-Poiseuille and Womersley Flows and Uncertainty Quantification, in “Proceedings of the Eleventh International Conference on Computational Fluid Dynamics (ICCFD11)” , Maui, HI, USA, July 11-15, 2022. (PDF)
3. X. Zhang, J Gomez-Paz, J. M. McDonough, Md M. Islam, Y. Andreopoulos, and H. Yu*, Volumetric Lattice Boltzmann Method for Wall Stresses of Image-based Pulsatile Flows, Scientific Reports, 12 (2022)1697. (PDF)
4. H. Yu*, X. Chen, Z. Wang, R. Chen, C. Lin, S. F. Kralik, Y. Zhao, A. P. Sawchuk, Validity of Patient-specific Computational Hemodynamics for Noninvasive Quantification of Blood Flow, in “Proceedings of 28th International Conference on Parallel Computational Fluid Dynamics Parallel CFD2016”, Kobe, Japan, May 2016 (K. Morinishi and K. Ono, Editors), pp. 150-151. (PDF)
5. H. Yu*, Z. Wang, Y. Zhao, A. P. Sawchuk, C. Lin, M. C. Dalsing, “GPU-accelerated Patient-Specific Computational Flow From Radiological Images to in vivo Fluid Dynamics”, (2015), in “Proceedings of 27th International Conference on Parallel Computational Fluid Dynamics Parallel CFD2015”, Montreal, Canada, May 2015. (W. G. Habashi and M. Fossati, Editors) (PDF)
6. H. Yu*, R. Chen, and L. Zhu, “GPU-accelerated Lattice Boltzmann method for direct numerical simulation of decaying isotropic turbulence with and without rotation “, (2014), in “Proceedings of 26th International Conference on Parallel Computational Fluid Dynamics Parallel CFD2014”, Trondheim, Norway, May 2014. (T. Kvamsdal , Editor) (PDF)
7. H. Yu*, X. Chen, Z. Wang, D. Deep, E. Lima, Y. Zhao, and S. D. Teague, Mass-conserved volumetric lattice Boltzmann method for complex flows with or without willfully moving boundaries, Phys. Rev. E, 89 (2014) 063304 (PDF)
8. H. Yu* and K. Zhao, “Rossby vortex simulation on paraboloidal coordinate system using Lattice Boltzmann method”, Physical Review E, 64 (2001) 056703. (PDF)
9. H. Yu* and K. Zhao, “Lattice Boltzmann method for compressible flows with high Mach number,” Physical Review E, 61 (2000) 3867. (PDF)
10. H. Yu* and K. Zhao, Modified high Mach number Lattice Boltzmann model, Acta Physics Sinica, 49(4) (2000) L816.
11. H. Yu* and K. Zhao, "A new lattice Boltzmann model for two-phase fluid", Chinese Physical Letter, 16 (1999) 271. (PDF)
12. H. Yu* and K. Zhao，High Mach number Lattice Boltzmann model, Acta Physics Sinica, 48(8)(1999) 1475-1481. (PDF)
13. H. Yu, "Lattice gas automaton for simulating hydromechanics." Physics Bulletin, 3 (1999) 4.
14. H. Yu* and Z. Han. "Numerical simulation of two-dimensional viscous fingering by the conformal mapping method", Physical Review E, 58 (1998) 6873. (PDF)
15. H. Yu, "A fast efficient method of converging divergent Fourier series", Chinese Journal of Computational Physics, 14(4, 5) (1997) 64. (PDF)

Computational/Experimental Hemodynamics for Medical Applications
16. S. An, H. Yu*, MD M. Islam, X. Zhang, Y. Zhan, J. J. Olivieri, J. Ambati, J. Yao, and B. D. Gelfand*, Effects of donor-specific microvascular anatomy on hemodynamic perfusion in human choriocapillaris, Scientific Reports, 13, 22666(2023).(PDF)
17. B. Shang, R. Chen, W. Yan, and H. Yu, GPU accelerated volumetric lattice Boltzmann model for image-based hemodynamics in portal hypertension, Computers and Fluids, 266, 15, 2023. 106038.(PDF)
18. W. Hong, H. Yu*, J. Chen, J. Talamantes, D. M. Rollins, X. Fang, J. Long, C. Xu, and A. P. Sawchuk, A Human-sized Mock Circulation Loop for in vitro Hemodynamic Characterization of Vascular Diseases, Fluids, 8, 198, 2023. (PDF)
19. A. P. Sawchuk*, J. Talamantes, W. Hong, R. Motaganahalli, and H Yu*, Development And Initial Validation Of A Modern Hemodynmaics Laboratory, Journal of Vascular Surgery, 76 (4) (2022) e73. (PDF)
20. C. Rong, R. Chen, W. Yan, H, Yu, and Y. Xu, Hemodynamic analysis of external iliac artery based on VLBM, Journal of Zhejiang University of Science and Technology, 34 (1) (2022) 7-16. (PDF)
21. A. P. Sawchuk*, W. Hong, J. Talamantes, MD M. Islam, X. Luo, and H Yu*, The Predictive Ability of the Renal Resistive Index and its Relationship to Duplex Ultrasound Waveform Propagation in the Aorta and Renal Arteries, Annals of Vascular Surgery, Apr 22: S0890-5096(2022)00202-3. (PDF)
22. H. Yu*, M. Khan, H. Wu, X. Du, R. Chen, D. M. Rollins, X. Fang, J. Long, C. Xu, M. Murphy, R. L. Motaganahallie, and A. P. Sawchuk. A new noninvasive and patient-specific hemodynamic index for assessing the severity of renal arterial stenosis, International Journal for Numerical Methods in Biomedical Engineering, 38(7) (2022) e3611. PMID: 35509229.(PDF)
23. H. Yu*, M. Khan, H. Wu, C. Zhang, X. Du, R. Chen, X. Fang, J. Long, and A. P. Sawchuk, Inlet and Outlet Boundary Conditions in Volumetric Lattice Boltzmann Method for Patient-specific Computational Hemodynamics in Aortorenal Arterial System, Fluids, 7(1) (2022) 30. (PDF)
24. A. P. Sawchuk, H. Yu*, J. Talamantes, W. Hong, D. Rollins, and R. Motaganahalli, A Deep Dive into the Meaning of the Renal Resistive Index, its Limited Correlation With Renal Function, and a Theoretical Way Forward to Improve its Usefulness, Journal of Vascular Surgery, 74(4)(2021), e381–e382. (PDF)
25. S. Abootorabi, A.Tripathi, H. Yu*, and D. P. Dávila. Computational Modeling of Intraocular Drug Delivery Supplied by Porous Implants, Biomechanics and Modeling in Mechanobiology, Drug Delivery and Translational Research, 11(5)(2021) 2134-2143. PMID: 33432523. (PDF)
26. H Yu*, C Rong, X Jin, Y Xu, M Murphy, R Motaganahalli, AP Sawchuk, Fast and Noninvasive Evaluation of In Vivo Pressure in Stenosed Aortoiliac Arteries, Journal of Vascular Surgery, 72 (3)(2020), e308-e309. (PDF)
27. H. Wu, M. Khan, X. Du, A. P. Sawchuk, and H. Yu*, Reliability Analysis for CTA-Based Non-invasive Pressure Quantification in Aortorenal Artery Systems, Circulation Research, 125 (suppl_1) (2019), A122.
28. H Yu*, M Khan, A. P. Sawchuk, Q. Wang, H. Lou, L. Zhang, X. Fang, H. Liang, and R. L. Motaganahalli. Fast, Non-invasive, and Patient-specific Assessment for Ischemic Severity of Arterial Stenosis, Arteriosclerosis, Thrombosis, and Vascular Biology, 39: A364 (Suppl_1)(2019), A364.
29. B. Gelfand, J. Ambati, S. An, R. Chen; H. Yu*, and J. Yao. Hemodynamic shear stress in the inner choroid primes endothelium for complement damage, Investigative Ophthalmology & Visual Science, 59(9)(2018), 3473.
30. H. Yu*, A Deb, M. Khan, R. Chen, Y. Yang. I-W Wang, Non-Invasive, Patient-Specific Assessment of LVAD Modeled with Consideration of LV Ejection and Function, Circulation Research, 123(Suppl_1) (2018) A229.
31. M. Khan, A. P. Sawchuk, A. Deb, R. Chen, R. L. Motaganahalli, X. Fang, and H. Yu*. Effective Three-element Windkessel Model based on Doppler Ultrasound Images for Noninvasive Quantification of Trans-stenotic Pressure Gradient in Aortorenal System, Circulation Research, 123(Suppl_1) (2018) A360.
32. A. P. Sawchuk, M. Khan, A. Deb, R. L. Motaganahalli, X. Fang, C. Xu, and H. Yu*. Non-invasive and patient-specific assessment of true severity of renal arterial stenosis for new guidelines for planning stent therapy, Journal of Vascular Surgery, 68(3)(2018) e64–e65.(PDF)
33. BD Gelfand, S. An, H. Yu*, R. Chen, J. Yao, and J. Ambati. Shear stress governs choroidal endothelial cell proliferation and homeostasis, Investigative Ophthalmology & Visual Science, 58 (8)(2017), 1102.
34. Z. Wang, Y. Zhao, H. Yu*, X. Chen, C. Lin, S. F. Kralik, G. D. Hutchins; Using flow feature to extract pulsatile blood flow from 4D flow MRI images, Proc. SPIE 10133, Medical Imaging 2017: Image Processing, 101331O (February 24, 2017). (PDF)
35. H. Yu*, X. Chen, Z. Wang, R. Chen, C. Lin, S. F. Kralik, P. Raveena, Integration of patient-specific computational hemodynamics and vessel wall shear stress into MRI diagnosis of vascular diseases, Circulation Research , 119 (2016) A235.
36. P. Sawchuk, R. Patil, H. Zhu, H. Yu*, R. Motaganahalli, and M. C. Dalsing, Noninvasive Measurement of Renovascular Resistance and the Meaning and Limitations of the Renal Resistance Index, Journal of Vascular Surgery, 64(3)(2016) 876-877.(PDF)
37. A. P. Sawchuk, H. Yu*, A. Mumbaraddi, and M. C. Dalsing, The Hemodynamics of Renovascular Hypertension and Atherosclerosis, Journal of Vascular Surgery, 62(3) (2015) 821-822.(PDF)
38. A. P. Sawchuk, A. Mumbaraddi, H. Yu*, and M. C. Dalsing, PC88. The Complex Hemodynamics of Renal Artery Atherosclerosis, Journal of Vascular Surgery, 61(6)(2015)141S-142S.
39. A. P. Sawchuk, H. Yu*, M. C. Dalsing, Rethinking the Cause-and-Effect Relationship Between Renovascular Hypertension and Renal Artery Stenosis, Journal of Vascular Surgery, 60:4(2014) 1109-1110.(PDF)

High-Performance Computation
40. S. An, H. Yu*, and J. Yao, GPU-accelerated Volumetric Lattice Boltzmann Method for Porous Media Flow, Journal of Petroleum Science and Engineering, 156(2017)546-552 . (PDF)
41. Z. Wang, Y. Zhao, A. P. Sawchuck, M. C. Dalsing, and H. Yu*, GPU Acceleration of Volumetric Lattice Boltzmann Method for Patient-specific Computational Hemodynamics, Computer & Fluids , 115(2015)192-200. (PDF)
42. H. Yu*, R. Chen, H. Wang, Z. Yuan, Y. Zhao, Y. An, Y. Xu, and L. Zhu, GPU accelerated lattice Boltzmann simulation for rotational turbulence, Computer & Mathematics with Applications, 67(2) (2014) 437-451.(PDF)

Porous-Media Flow
43. S. An, Y. Zhan, J. Yao, H Yu*, and V. Niasar. A Greyscale Volumetric Lattice-Boltzmann Method for Upscaling Pore-Scale Two-Phase Flow, Advances in Water Resources, 144(2020) 103711.(PDF)
44. S. An, H. Yu*, Z. Wang, R. Chen, B. Kapadia, J. Yao. Unified Mesoscopic Modeling and GPU-accelerated Computational Method for Image-based Pore-scale Porous Media Flows, International Journal of Heat and Mass Transfer, 115(2017)1192-1202. (PDF)
45. Y. Xu, CQ Liu, H. Yu*, “New studying of lattice Boltzmann method for two-phase driven in porous media”, Applied Mathematics and Mechanics, 23 (2002) 387-393. (PDF)

Bubble Coalescence
46. R. Chen, S. Zhou, L. Zhu, L. Zhu, W. Yan, and H. Yu*, Numerical and experimental study for 3D coalescence-induced detachment of microbubble, Physics of Fluids, 917(2021) 043320. (PDF)
47. R. Chen, H. Yu*, J. Zeng, and L. Zhu. General Power-law Temporal Scaling for Unequal Microbubble Coalescence, Physical Review E, 101(2020), 023106. PMID: 32168553. (PDF)
48. R. Chen, J. Zeng, and H. Yu*. Mechanism of Damping Oscillation in the Bubble Coalescence, Computer & Fluids, 183(4)(2019), 38-42. (PDF)
49. R. Chen, H. Yu*, Y. Xu, and L. Zhu. Scalings of inverse energy transfer and energy decay in 3-D decaying isotropic turbulence with and without rotation, Journal of Applied and Computational Mechanics, 5(4)(2019) 639-646. (PDF)
50. R. Chen, H. Yu*, and L. Zhu. Effects of Initial Conditions on the Coalescence of Micro-bubbles, Journal of Mechanical Engineering Science, 232(2018)457-465. (PDF)
51. S. Zhou, Y. Cao, R. Chen, T. Sun, F. Carlo, H. Yu*, L. Zhu. Study on coalescence dynamics of unequal-sized microbubbles captive on a solid substrate, Experimental Thermal and Fluid Science, 98(2018), 362-368. (PDF)
52. R. Chen, H. Yu*, L. Zhu, T. Lee, and R. M. Patil, Spatial and Temporal Scaling of Unequal Microbubble Coalescence, 63(4): 1441-1450, AIChE Journal, 2017. (PDF)
53. R. Chen, H. Yu*, L. Zhu, and T. Lee, Numerical Simulation and Analysis of Size Inequality on Microbubble Coalescence, in “Proceedings of 28th International Conference on Parallel Computational Fluid Dynamics”, Kobe, Japan, May 2016 (K. Morinishi and K. Ono, Editors), pp. 114-115. (PDF)

Computational/Experimental Turbulence
54. J. Gomez, H. Yu*, and Y. Andreopoulos, The role of flow reversals in transition to turbulence and relaminarization of pulsatile flows, Journal of Fluid Mechnaics, 917(6)(2021) A27. (PDF)
55. L. Chevillard, E. Leveque, F. Taddia, C. Meneveau, H. Yu*, and C. Rosales, Local and nonlocal pressure Hessian effects in real and synthetic fluid turbulence, Physics of Fluids, 23 (2011) 095208. (PDF)
56. H. Yu* and C. Meneveau, Lagrangian Refined Kolmogorov Similarity Hypothesis for Gradient Time-evolution in Turbulent Flows, Physical Review Letters, 104 (2010) 084502. (PDF)
57. H. Yu* and C. Meneveau, Scaling of conditional Lagrangian time correlation functions of velocity and pressure gradient magnitudes in isotropic turbulence, Flow, Turbulence and Combustion, 85 (2010) 457 – 472. (PDF)
58. H. Yu* and S. S. Girimaji, Study of axis-switching and stability of laminar rectangular jets using lattice Boltzmann method, Computers & Mathematics with Application, 55 (2008) 1611. (PDF)
59. H. Yu*, and S. S. Girimaji, Extension of compressible ideal-gas RDT to general mean velocity gradients, Physics of Fluids, 19 (2007) 041702. (PDF)
60. H. Yu*, L-S Luo, and S. S. Girimaji, Large-eddy simulation of a square turbulent jet using multi-relaxation-time lattice Boltzmann model, Computers & Fluids, 35 (2006) 957-965. (PDF)
61. H. Yu* and S. S. Girimaji, Lattice Boltzmann equation simulation of rectangular jet (AR=1.5) instability, Physica A, 362 (2006) 151-157. (PDF)
62. H. Yu*, and S. S. Girimaji, Near-field mixing in low aspect ratio rectangular jet turbulent flows, Physics of Fluids, 17 (2005), 125106. (PDF)
63. H. Yu*, S. S. Girimaji, and L-S Luo, Lattice Boltzmann simulations of decaying homogeneous isotropic turbulence with and without system rotation, Physical Review E, 71 (2005) 204501. (PDF)
64. H. Yu*, S. S. Girimaji, and L-S Luo, DNS and LES of decaying homogeneous isotropic turbulence with and without system rotations using lattice Boltzmann method, Journal of Computational Physics, 209 (2005) 599-616. (PDF)
65. H. Yu*, L.-S. Luo, and S. S. Girimaji, Scalar mixing and reaction simulations using lattice Boltzmann method, International Journal of Computational Engineering Science, 156 (2002) 1. (PDF)

Turbulence Database
66. H. Yu*, K. Kanov, E. Perlman, J. Graham, E. Frederix, R Burns, A. Szalay, G. Eyink and C. Meneveau, Studying Lagrangian dynamics of turbulence using on-demand fluid particle tracking in a public turbulence database, Journal of Turbulence, 13 (2012), 1-29. (PDF)
67. C. Meneveau & H. Yu*, “Public database-enabled analysis of Lagrangian statistics in isotropic turbulence” (2009), in “Proceedings of Euromech Colloquium 512: Small scale turbulence and related gradient statistics”, Accademia delle Scienze di Torino (D. Tordella & K. R. Sreenivasan, editors).

Corrosion
68. H. Yu*, J. Zhang, and N. Li, Lattice Boltzmann simulation of mass transfer in thermally driven cavity flows, Progress in Computational Fluid Dynamics, 8 (2008) 206. (PDF)
69. H. Yu*, N. Li, and R. E Ecke, Scaling in laminar natural convection in laterally heated cavities: Is turbulence essential in the classical scaling of heat transfer? Physical Review E, 77 (2007) 026303. (PDF)

Solar Energy
70. R. Chen, J. Shao, Y. Zheng, H. Yu*, Y. Xu, Lattice Boltzmann simulation for complex flow in a solar wall, Communications in Theoretical Physics, 59 (2013) 370 - 374. (PDF)

General Fluid Dynamics
71. H. Yu*, X. Chen, Y. Xu, and Y. Joglekar, Scaling of PT-asymmetries in viscous flow with PT-symmetric inflow and outflow, Journal of Physics A: Mathematical and Theoretical, 48(2015)035501. Selected for inclusion in the Journal of Physics A Highlights of 2015 collection (http://iopscience.iop.org/1751-8121/page/Highlights-of-2015) (PDF)
72. X. Chen, H. Yu*, J. Yogesh, Y. Zheng, Y. Xu, and F. Wu, The influence of different driving patterns on parity time-reversal symmetry, Acta. Phys. Sin., 63(6) (2014) 060206.
73. N. Chen and H. Yu*, Mechanism of axis switching in low aspect-ratio rectangular jets, Computer & Mathematics with Applications, 67(2) (2014) 437-444. (PDF)
74. T. A. Lavin, S. S. Girimaji, S. Suman, and H. Yu*, Flow-thermodynamics interactions in rapidly-sheared compressible turbulence, Theoretical and Computational Fluid Dynamics, 26 (2012) 501-522. (PDF)
75. H. Yu* and D. Livescu, Linear stability analysis of Rayleigh-Taylor instability in cylindrical geometry, Physics of Fluids, 20 (2008) 104103. (PDF)
76. H. Yu* & D. Livescu, Convergence Effects on Acceleration driven Instability, in “Section 2: Applied Mathematics, Fluid Dynamics, and Magnetohydrodynamics, ADTSC Science Highlights 2008”, pp. 26, Los Alamos National Laboratory.
77. H. Yu* and K. Zhao, Pattern select: nonsingular Saffman-Taylor finger and its dynamic evolution with zero surface tension, in Fractal 2000 – Complexity and Fractals in the Sciences, p. 279-286, editor: M. M. Novak, Singapore: World Scientific, 2000. ISBN: 9810242921.
78. Yu*, H. and Zhao, K., Width selection of nonsingular Saffman-Taylor finger with zero surface tension, Journal of Zhejiang University, 31(1) (1999) 270.
79. Yu*, H., The evolution of nonsingular Saffman-Taylor finger with small surface tension, Journal of Zhejiang Normal University, 21(1) (1998) 30.
80. K. Zhao and H. Yu*, Nonsingular Saffman-Taylor finger, Communication in Nonlinear Sciences and Numerical Simulation, 5 (1997) 28.

Nonlinear Physics
81. H. Yu*, Similarities reductions of the 2+1 dimensional high degree CDGSK equation, Communication in Nonlinear Sciences & Numerical Simulation, 1 (1996) 28.
82. H. Yu* and J. Zhang, Similarity solutions of the super KdV equation, Applied Mathematics and Mechanics, 16 (1995) 901.
83. Yu*, H. and Zhang, J., Simplifying the KP equation with symmetry, Journal of Hangzhou University, 22 (1995) 94.
84. Yu*, H. and Zhang J., Analysis of the Lie symmetry and the invariable construction in non-integrated and Non-Conservative Kinetics System, Journal of Hangzhou University, 22 (1995) 104.
85. Yu*, H., Noether's theory for nonholonomic controllable dynamic systems relative to non-inertial reference frames, Journal of Zhejiang Normal University, 18 (1995) 30.
86. Yu*, H. and Zhang, J., Symmetric similarity of modified KP equation, Journal of Jiujiang Normal College, 75 (1995) 19.
87. J. Zhang and H. Yu*, New similarities of the fifth-order KdV equation. Communication Theory Physics 22 (1994) 245.
88. Yu* H. and Yu, J., A new method to construct conservative laws of nonholonomic non-potential dynamics systems. In Chinese Nonholonomic Dynamics 30 Years. Editors: Chen Bin and Mei Fengxiang, Henan University Publisher, 1994.
89. Hong, G., and Yu*, H., A method of integration of canonical equation for nonholonomic systems relative to the motion of non-inertial frame, Journal of Luoyang Technical College, 15(1994) 66.
90. H. Yu*, J. Zhang, and Y. Xu. Noether's theory for nonholonomic dynamic systems relative to non-inertial references, Applied Mathematics and Mechanics, 14 (1993) 527.
91. Zhang, J., and Yu*, H., Solving non-simultaneous variational equations of nonholonomic systems by using its first integral, Journal of Xinjiang Normal University, 10 (1993) 43.
92. Yu*, H., The movable integration of relative dynamic equations of nonholonomic systems, Journal of Zhejiang Normal University, 16 (1993) 43.
93. Yu*, H., Lagrange equation in the non-inertial reference, Journal of Zhejiang Normal University, 15 (1992) 52.  Cited for excellence and included in the book Collection of Chinese Scientific and Technical Productions during the Eighth "Five Year Plan."
94. Yu*, H., Jiefang Zhang and Ping Han, Integration of high order relative dynamic equations for nonholonomic systems, Journal of Zhoushan Normal College, 29 (1992) 39.

Education
95. R. Nalim, L. Li, P. Orono, R. Helfenbein, H. Yu*, and M. Mital, Project-Enhanced Learning in Challenging Engineering Science Courses, American Society for Engineering Education, 2012 IL/IN Sectional Conference, Valparaiso University, Valparaiso, Indiana.
96. Yu*, H. and Zhang D., A prospective scientific field, Remote Advanced Education, 3(1992) 66.
97. Yu*, H., Particle motion on a coarse sphere surface, Remote Advanced Education, 5(1990) 53.
98. Yu*, H., Motion investigation for a particle on a coarse sphere, Journal of Zhejiang Normal University, 14 (1991) 58.
99. Yu*, H., Two ways to estimate volume parameter b for Van Der Waals Gas, Remote Advanced Education, 1(1990) 53.