Computational Transport Processes

DVP's Selected Publications

Turbulent Transport

Nguyen, K.T., and D.V. Papavassiliou, “Flow effects on the kinetics of a second-order reaction,” in press, Chemical Engineering Journal, 2008.

Nguyen, K.T., and D.V. Papavassiliou, “Effects of a reacting channel wall on turbulent mass transfer,” Int. J. Heat Mass Transf., 51, 2940-2949, 2008.

Le, P.M., and D.V. Papavassiliou, “On the scaling of heat transfer using thermal flux gradients for fully developed turbulent channel and Couette flows,” Int. Com. Heat Mass Transfer, 35(4), 404-412, 2008.

Le, P.M., and D.V. Papavassiliou, “On temperature prediction at low Re turbulent flows using the Churchill turbulent heat flux correlation,” Int. J. Heat Mass Transfer, 49, 3681-3690, 2006.

Le, P.M., and D.V. Papavassiliou, “Turbulent heat transfer in plane Couette flow,”  J. of Heat Transf., Trans. ASME., 128, 53-62, 2006.

Le, P.M., and D.V. Papavassiliou, “Turbulent dispersion from elevated line sources in plane channel and plane Couette flow,” AIChE J., 51(9), 2402-2414, 2005.

Mitrovic, B.M., Le, P.M., and D.V. Papavassiliou, “On the Prandtl or Schmidt number dependence of the turbulence heat or mass transfer coefficient,” Chem. Eng. Sci., 59(3), 543-555, 2004.

Mitrovic, B.M., and D.V. Papavassiliou, “Effects of a first-order chemical reaction on turbulent mass transfer,” Int. J. Heat Mass Transfer, 47(1), 43-61, 2004.

Mitrovic B.M., and D.V. Papavassiliou, “Transport properties for turbulent dispersion from wall sources,” AIChE J., 49(5), 1095-1108, 2003.

Papavassiliou, D.V, "Turbulent transport from continuous sources at the wall of a channel," Int. J.  Heat Mass Transfer, 45(17), 3571-3583, 2002.

Papavassiliou, D.V., "Scalar dispersion from an instantaneous line source at the wall of a turbulent channel for medium and high Prandtl number fluids," Int. J. Heat and Fluid Flow, 23(2), 161-172, 2002.

Na, Y., Papavassiliou, D.V., and T.J. Hanratty, "Use of Direct Numerical Simulation to study the effect of Prandtl number on temperature fields", Int. J. Heat and Fluid Flow, 20(3), 187-195, 1999.

Papavassiliou, D.V., and T.J. Hanratty, "Transport of a passive scalar in a turbulent channel flow", Int. J. Heat Mass Transfer, 40(6), 1303-1311, 1997.

Papavassiliou, D.V., and T.J. Hanratty, "The use of Lagrangian methods to describe turbulent transport of heat from the wall", Ind. Eng. Chem. Res., 34, 3359-3367, 1995.

Micro- and Nano-fluidics

Voronov, R., Papavassiliou, D.V., and L.L. Lee, “A Review of Fluid Slip over Superhydrophobic Surfaces and its Dependence on Contact Angle,” Ind. Eng. Chem. Res., 47(8), 2455-2477, 2008.

 

Duong, H.M., Papavassiliou, D.V., Mullen, K.J. and S. Maruyama, “Computational modeling of thermal conductivity of single walled carbon nanotube polymer composites,” Nanotechnology, 19(6), Art. No. 065702, 2008.

                                                                                                                                                                                          

Voronov, R., Papavassiliou, D.V., and L.L. Lee, “Slip length and contact angle over hydrophobic surfaces,” Chem. Phys. Lett., 441(4-6), 273-276, 2007.

 

Voronov, R., Papavassiliou, D.V., and L.L. Lee, “Boundary slip and wetting properties of interfaces: Correlation of the contact angle with the slip length,” J. Chem. Phys., 124, 204701, 2006.

 

Papavassiliou, D.V., “Understanding macroscopic heat/mass transfer using meso- and macro-scale simulations,” in Model Reduction and Coarse-Graining Approaches for Multiscale Phenomena,  (edited by A.N. Gorban, N. Kazantzis, Y.G. Kevrekidis, H.C. Ottinger, C. Theodoropoulos), pp. 489-515, Springer-Verlag, 2006.

 

Ford, A., and D.V. Papavassiliou, “Flow around surface-attached Carbon Nanotubes,” Ind. Eng Chem. Res.,  45(5), 1797-1804, 2006.

Duong, H.M., Papavassiliou, D.V., Lee, L.L., and K.J. Mullen, “Random walks in nanotube composites: Improved algorithms and the role of thermal boundary resistance,” App. Phys. Lett., 87, 013101, 2005.

Thummala, N., and D.V. Papavassiliou, “Simulation of heat transfer with LBM and Lagrangian methods for microfluidic applications,” paper HT2005-72313, Proceedings 2005 ASME Summer Heat Transfer Conference, San Francisco, CA, July 17-22, 2005.

Biological systems, biofluids

Nguyen, K.T., Clark, C.D., Chancellor, T.J., and D.V. Papavassiliou, “Carotid geometry effects on blood flow and on risk for vascular disease,” Journal of Biomechanics, 41, 11-19, 2008.

Coupled Jet Flows for Meltblowing – applied CFD

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Effects of the polymer fiber on the flow field from a slot melt blowing die,” Ind. Eng. Chem. Res., 47(3), 935-945, 2008.

 

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Effects of the polymer fiber on the flow field from an annular melt blowing die,” Ind. Eng. Chem. Res., 46(2), 655-666, 2007.

 

Marla, V.T., Shambaugh, R.L., and D.V. Papavassiliou, "Use of an infrared camera for accurate determination of the temperature of polymer filaments,” Ind. Eng. Chem. Res., 46(1), 336-344, 2007.

 

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Analysis of the temperature field from multiple jets in the Schwarz melt blowing die using computational fluid dynamics,” Ind. Eng. Chem. Res., 45(14), 5098-5109, 2006.

 

Marla, V.T., Shambaugh, R.L., and D.V. Papavassiliou, "Using swirl dies to spin solid and hollow fibers,” Ind. Eng Chem. Res.,  45(7), 2331-2340, 2006.

Marla, V., Shambaugh, R.L., and D.V. Papavassiliou, “Modeling the melt blowing of hollow fibers,” Ind. Eng. Chem. Res.,  45(1), 407-415, 2006.

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Analysis of multiple jets in the Schwarz melt blowing die using computational fluid dynamics,” Ind. Eng. Chem. Res. , 44(23), 8922-8932, 2005.

 

Moore, E.M., Shambaugh, R.L., and D.V. Papavassiliou, “Analysis of Isothermal Annular Jets: Comparison of CFD and Experimental Data,” J. Appl. Polym. Sci., 94(3), 909-922, 2004.

 

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Effects of temperature and geometry on the flow field of the melt blowing process,” Ind. Eng. Chem. Res., 43(15), 4199-4210, 2004.

 

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Effects of die geometry on the flow field of the melt blowing process,” Ind. Eng. Chem. Res., 42(22), 5541-5553, 2003.

 

Krutka, H.M., Shambaugh, R.L., and D.V. Papavassiliou, “Analysis of a melt blowing die: comparison of CFD and experiments,” Ind. Eng. Chem. Res., 41(20), 5125-5138, 2002.

Flow in Porous Media

Lao, H-W, Neeman, H.J., and D.V. Papavassiliou, “A pore network model for the calculation of non-Darcy flow coefficients in fluid flow through porous media,” Chem. Eng. Com., 191(10), 1285-1322, 2004.

Lao, H-W., Neeman, H.J. and D.V. Papavassiliou, "Stochastic prediction of pore media properties," Computational Technologies for Fluid/Thermal/Chemical Systems with Industrial Applications, PVP-Vol. 424-2,185-195,  ASME Conference, Atlanta, July, 2001.

Garanzha, V.A., Konshin, V.N., Lyons, S.L., Papavassiliou, D.V., and G. Qin, "Validation of non-Darcy well models using direct numerical simulation," in Numerical Treatment of Multiphase Flows in Porous Media, (Chen, Ewing & Shi, editors), pp. 156-169, Lecture Notes in Physics, Vol. 552, Springer-Verlag, 2000.

Papavassiliou, D.V., S.L. Lyons, and M.E. Henderson, "Simulation of multiphase non-Darcy flow through porous media," Computational Technologies for Fluid/Thermal/Chemical Systems with Industrial Applications, PVP-Vol. 397-1, 149-156, ASME Conference, Boston, August, 1999.

Ewing, R.E., Lazarov, R., Lyons, S.L., Papavassiliou, D.V., Pasciak , J., and G. Qin, "Numerical well model for non-Darcy flow through isotropic porous media", Computational Geosciences, 3(3-4), 185-204, 1999.

Papavassiliou, D.V., and S.L. Lyons, "Non-Darcy flow through porous media. Numerical and physical issues", Proceedings, 1st IMuST Annual Meeting, Santa Barbara, February 1998.

Multiphase Flow

Oladunni, O.O., Trafalis, T.B., and D.V. Papavassiliou, “Knowledge-based Support Vector Machines Applied to Vertical Two-Phase Flow,” in Computational Science – ICCS 2006: PT 1 , Proceedings Lectures Notes in Computer Science.,  (Ed:  V.N. Alexandrov, G.D. van Albada, P.M.A. Sloot, J.Dongarra), 3991, 188-195, 2006.

 

Trafalis, T.B., Oladunni, O., and D.V. Papavassiliou, “Two-Phase Flow Regime Identification with a Multi-Classification SVM Model,” Ind. Eng. Chem. Res., 44(12), 4414-4426, 2005

Structure of Turbulence

Guenther, A., Papavassiliou, D.V., Warholic, M.D. and T.J. Hanratty, "Turbulent flow in a channel at low Reynolds number", Experiments in Fluids, 25, 503-511, 1998.

Hanratty, T.J., and D.V. Papavassiliou, "The role of wall vortices in producing turbulence", in Self Sustaining Mechanisms of Wall Turbulence, (Panton, R.L. editor), Chapter 5, pp. 83-108, Computational Mechanics Inc., 1997

Hanratty, T.J. and D.V. Papavassiliou, "Reynolds number effects on the scaling of wall turbulence", Proceedings, Eleventh Symposium on Turbulent Shear Flows, paper 11-8, Toulouse, France, September 1997.

Papavassiliou, D.V., and T.J. Hanratty, "Interpretation of large scale structures in a turbulent plane Couette flow", Int. J. Heat and Fluid Flow, 18, 55-69, 1997.

High Performance Computing

Neeman, H.J., Lao, H-W., Simpson, D., and D.V. Papavassiliou, "Multiscale characterization of porous media properties for hydrocarbon reservoir simulation," in Commercial Applications for High Performance Computing, Howard J. Siegel, editor, Proceedings of SPIE Vol. 4528, 87-97, 2001.

 

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