Ugo Piomelli - me.queensu.ca · 7.U. Piomelli, P. Moin, and J. H. Ferziger \Large eddy simulation...

$: Ugo Piomelli - me.queensu.ca · 7.U. Piomelli, P. Moin, and J. H. Ferziger \Large eddy simulation of the ow in a transpired channel." AIAA J. Thermophysics and Heat Transfer 5, pp.$
Ugo Piomelli

Curriculum Vitæ

May 2019

PERSONAL INFORMATION

A. Education

1. Ph. D., Mechanical Engineering, Stanford University, Stanford, California. January 1988.

2. M. S., Aerospace Engineering, University of Notre Dame, Notre Dame, Indiana. January 1984.

3. Dr. Ing., Aeronautical Engineering, Universita degli Studi di Napoli, Naples, Italy. Cum Laude.July 1979.

B. Employment history

1. Professor, Department of Mechanical and Materials Engineering. Queen’s University, Kingston,Ontario, Canada. August 2008–Present.

2. Emeritus Professor, Department of Mechanical Engineering. University of Maryland, CollegePark, Maryland. November 2008–Present.

3. Professor, Department of Mechanical Engineering. University of Maryland, College Park, Mary-land. July 2000–July 2008.

4. Associate Chair and Director of Graduate Studies, Department of Mechanical Engineering. Uni-versity of Maryland, College Park, Maryland. July 2001–July 2006.

5. Associate Professor in the Department of Mechanical Engineering. University of Maryland, Col-lege Park, Maryland. Aug. 1993–June 2000.

6. Visiting Professor, Ecole Nationale Superieure d’Hydraulique et de Mecanique de Greno-ble, Grenoble, France. Jan. 1999–Feb. 1999.

7. Acting Director of Graduate Studies, Department of Mechanical Engineering, University of Mary-land, College Park, Maryland. Aug. 1996–Aug. 1997.

8. Visiting Professor, Department of Energetics. University of Naples, Naples, Italy. May 1997–Jun. 1997.

9. Visiting Scholar, Department of Theoretical and Applied Mechanics. University of Illinois atUrbana-Champaign, Urbana, Illinois. Jan. 1994–Apr. 1994.

10. Assistant Professor, Department of Mechanical Engineering. University of Maryland, CollegePark, Maryland. Dec. 1987–Aug. 1993.

11. Research Assistant, Department of Mechanical Engineering. Stanford University, Stanford, Cali-fornia. Sept. 1983–Dec. 1987.

12. Teaching Assistant, Department of Aerospace and Mechanical Engineering. University of NotreDame, Notre Dame, Indiana. Aug. 1981–Aug. 1983.

C. Membership in professional societies

1. Royal Society of Canada, Fellow.

2. American Physical Society, Fellow.

3. American Society of Mechanical Engineers, Fellow.

4. American Institute of Aeronautics and Astronautics, Associate Fellow.

5. Institute of Physics, Elected Fellow in 2004.

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SCHOLARLY ACTIVITIES

Bibliometrics: 8,099 citations; h-index=33 (Web of Science); 17,120 citations, h-index=46(Google Scholar). Students working under my supervision are boldfaced, Postdoctoral Fellows are under-lined.

A. Articles in refereed journals.

1. M. J. Lee, U. Piomelli, and W. C. Reynolds “Useful formulas in the rapid distortion theory ofhomogeneous turbulence.” Phys. Fluids 29, pp. 3471–3474, 1986.

2. U. Piomelli, P. Moin, and J. H. Ferziger “Model consistency in large eddy simulation of turbulentchannel flows.” Phys. Fluids 31, pp. 1884–1891, 1988.Also appeared as AIAA Paper 87-1446, 1987.

3. U. Piomelli, J.-L. Balint, and J. M. Wallace “On the validity of Taylor’s hypothesis for wall-bounded flows.” Phys. Fluids A 1, pp. 609–611, 1989.

4. Y. Guezennec, U. Piomelli, and J. Kim “On the shape and dynamics of wall structures in turbulentchannel flow.” Phys. Fluids A 1, pp. 764–766, 1989.Also appeared as Conditionally-averaged structures in wall-bounded flows in Studying TurbulenceUsing Numerical Databases – Proceedings of the 1987 Summer Program, pp. 263-272, Center forTurbulence Research, Stanford, California, 1987.

5. U. Piomelli, J. H. Ferziger, P. Moin, and J. Kim “New approximate boundary conditions for largeeddy simulations of wall-bounded flows.” Phys. Fluids A 1, pp. 1061–1068, 1989.

6. U. Piomelli, T. A. Zang, C. G. Speziale, and M. Y. Hussaini “On the large-eddy simulation oftransitional wall-bounded flows.” Phys. Fluids A 2, pp. 257–265, 1990.Also appeared as ICASE Report No. 89-55, ICASE, NASA Langley Research Center, Hampton,Virginia, 1989. Also appeared as “On the application of large-eddy simulation to transitional wall-bounded flows,” in Laminar-Turbulent Transition, eds. D. Arnal and R. Michel (Springer-Verlag,Berlin), pp. 693–698, 1990.

7. U. Piomelli, P. Moin, and J. H. Ferziger “Large eddy simulation of the flow in a transpiredchannel.” AIAA J. Thermophysics and Heat Transfer 5, pp. 124–128, 1991.Also appeared as AIAA Paper 89-0375, 1989.

8. U. Piomelli and T. A. Zang “Large-eddy simulation of transitional channel flow.” Com-puter Phys. Comm. 65, pp. 224–230, 1991.Also appeared in IMACS 1st International Conference on Computational Physics, Boulder, Col-orado, June 10–15, 1990, and as ICASE Report No. 90–80, ICASE, NASA Langley Research Cen-ter, Hampton, Virginia, 1990.

9. M. Germano, U. Piomelli, P. Moin, and W. H. Cabot “A dynamic subgrid-scale eddy viscositymodel.” Phys. Fluids A 3, pp. 1760–1765, 1991.Also appeared in Studying Turbulence Using Numerical Databases III – Proceedings of the 1990Summer Program, pp. 5-17, Center for Turbulence Research, Stanford, California, 1990.

10. U. Piomelli, W. H. Cabot, P. Moin, and S. Lee “Subgrid-scale backscatter in turbulent andtransitional flows.” Phys. Fluids A 3, pp. 1766–1771, 1991.Also appeared in Studying Turbulence Using Numerical Databases III – Proceedings of the 1990Summer Program, pp. 19–30, Center for Turbulence Research, Stanford, California, 1990.

11. H. Esmaili and U. Piomelli “Temporal development of turbulent boundary layers with embeddedstreamwise vortices.” Theoret. Comput. Fluid Dynamics 6, pp. 369–380, 1992.Also appeared as “Large-eddy simulation of turbulent boundary layers with embedded streamwisevortices,” AIAA Paper 92-0552, 1992.

12. U. Piomelli, L. Ong, J. M. Wallace and F. Ledhari “Reynolds stress and vorticity in turbulentwall flows.” Applied Scientific Research 51, pp. 365–370, 1993.Also appeared in Advances in Turbulence IV, ed. F.T.M. Nieuwstadt, (Kluwer, Dordrecht), 1993.

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13. U. Piomelli “High Reynolds number calculations using the dynamic subgrid-scale stress model.”Phys. Fluids A 5, pp. 1484–1490, 1993.

14. N. M. El-Hady, T. A. Zang and U. Piomelli “Application of the dynamic subgrid-scale model toaxisymmetric transitional boundary layer at high speed.” Phys. Fluids 6, pp. 1299–1309, 1994.Also appeared as “Dynamic subgrid-scale modeling for high-speed transitional boundary layer”in Engineering Applications of Large Eddy Simulations–1993, eds. S.A. Ragab and U. Piomelli,(ASME), pp. 103–112, 1993.

15. E. Balaras, C. Benocci, and U. Piomelli “Finite difference computations of high Reynolds numberflows using the dynamic subgrid-scale model.” Theoret. Comput. Fluid Dyn. 7, pp. 207–216, 1995.

16. U. Piomelli and J. Liu “Large-eddy simulation of rotating channel flows using a localized dynamicmodel.” Phys. Fluids 7, pp. 839–848, 1995.Also appeared in Application of Direct and Large eddy simulation to transition and turbulence,AGARD Conference Proceedings 551, pp. 3-1–3-9, AGARD, Neuilly-sur-Seine, 1994.

17. U. Piomelli, Y. Yu and R. J. Adrian “Subgrid-scale energy transfer and turbulence structure.”Phys. Fluids 8, pp. 215–224, 1996.

18. E. Balaras, C. Benocci, and U. Piomelli “Two-layer approximate boundary conditions for large-eddy simulations.” AIAA J. 34, pp. 1111–1119, 1996.

19. J. A. Murray, U. Piomelli and J. M. Wallace “Spatial and temporal filtering of experimentaldata for a priori studies of subgrid-scale stresses.” Phys. Fluids 8, pp. 1978–1980, 1996.

20. J. Liu, U. Piomelli and P. R. Spalart “Interaction between a spatially growing turbulent boundarylayer and embedded streamwise vortices.” J. Fluid Mech. 326, pp. 151–179, 1996.Also appeared as “Large-eddy simulation of counter-rotating vortices in a boundary layer” inTurbulence 94: Theory and experiments, ed. R. Benzi, (Kluwer, Dordrecht), pp. 324–329, 1995.Also appeared as “Interaction of embedded streamwise vortices with a flat-plate boundary layer,”by J. Liu and U. Piomelli, in Engineering Applications of Large Eddy Simulations–1993, eds. S.A. Ragab and U. Piomelli, (ASME), pp. 45–52, 1993.

21. U. Piomelli, G. N. Coleman and J. Kim “On the effects of non-equilibrium on the subgrid-scalestresses.” Phys. Fluids 9, pp. 2740–2748, 1997.Also appeared as “Subgrid-scale stress models for non-equilibrium flows” in Mathematical mod-elling of turbulent flows, eds. H. Daiguji and Y. Miyake, (Japan Soc. Comput. Fluid Dynam-ics, Tokyo), pp. 87–94, 1995.

22. X. Huai, R. D. Joslin and U. Piomelli “Large-eddy simulation of transition to turbulence inboundary layers.” Theoret. Comput. Fluid Dyn. 9, pp. 149–163, 1997.

23. U. Piomelli, C. L. Streett and S. Sarkar “On the computation of sound by large-eddy simulations.”J. Engineering Math. 32, pp. 217–236, 1997.

24. U. Piomelli “Large-eddy simulation: achievements and challenges.” Progress Aero. Sci. 35,pp. 335–362, 1999.

25. X. Huai, R. D. Joslin and U. Piomelli “Large-eddy simulation of transition in swept-wingboundary-layer flows.” J. Fluid Mech. 381, pp. 357–380, 1999.Also appeared as “Large-eddy simulation of boundary layer transition on a swept wing,” in Tran-sition, Turbulence and Combustion, Vol. I, eds. M. Y. Hussaini, T. B. Gatski and T. L. Jack-son, (Springer-Verlag, New York), pp. 369–378, 1994.Also appeared as “Large-eddy simulation of laminar-turbulent transition in a swept-wing bound-ary layer,” AIAA Paper No. 97-0750, 1997.

26. F. Sarghini, U. Piomelli and E. Balaras “Scale-similar models for large-eddy simulations.” Phys.Fluids 11, pp. 1596–1607, 1999.

27. V. Armenio, U. Piomelli and V. Fiorotto “Effect of the subgrid scales on particle motion.” Phys.Fluids 11, pp. 3030–3042, 1999.Also appeared as “On the application of large-eddy simulation to particle-laden flows” in Proc.Int. Symposium on Turbulence and Shear Flow Phenomena, Santa Barbara, CA, 1999.

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28. P. A. Chang, III, U. Piomelli and W. K. Blake “Relationship between wall pressure and velocity-field sources.” Phys. Fluids 11, pp. 3334-3348, 1999.

29. A. Pascarelli, U. Piomelli and G. V. Candler “Multi-block large-eddy simulation of turbulentboundary layers.” J. Comput. Phys. 157, pp. 256–279, 2000.Also appeared in Recent advances in DNS and LES, edited by D. Knight and L. Sakell, (KluwerAcademic Publishers, Dordrecht), pp. 349–359, 1999.

30. M. P. Martın, U. Piomelli and G. V. Candler “Subgrid-scale models for compressible large-eddysimulations.” Theoret. Comput. Fluid Dynamics 13, pp. 361–376, 2000.Also appeared as “A priori tests of SGS models in compressible turbulence” in 3rd ASME/JSMEJoint Fluids Engineering Conference, FEDSM 99-7313 (ASME) 1999.

31. N. Li, E. Balaras and U. Piomelli “Inflow conditions for large-eddy simulations of mixing layers.”Phys. Fluids, 12, pp. 935–938, 2000.

32. U. Piomelli, E. Balaras and A. Pascarelli “Turbulent structures in accelerating boundary layers.”J. of Turbulence 1, pp. 1–16, 2000.

33. C. Kannepalli and U. Piomelli “Large-eddy simulation of a three-dimensional shear-driven tur-bulent boundary layer.” J. Fluid Mech. 423, pp. 175–203, 2000.Also appeared in Direct and large-eddy simulation III, eds. P. R. Voke, N. D. Sandham and L.Kleiser, (Kluwer Academic Publishers, Dordrecht), pp. 87–98, 1999.

34. V. Armenio and U. Piomelli “A Lagrangian mixed subgrid-scale model in generalized coordinates.”Flow, Turbulence and Combustion 65, pp. 51–81, 2000.Also appeared in Direct and large-eddy simulation III, eds. P. R. Voke, N. D. Sandham and L.Kleiser, (Kluwer Academic Publishers, Dordrecht), pp. 135–146, 1999.

35. A. Scotti and U. Piomelli “Numerical simulation of pulsating channel flow.” Phys. Fluids 13,pp. 1367–1384, 2001.

36. E. Balaras, U. Piomelli and J. M. Wallace “Self-similar states in turbulent mixing layers.” J.Fluid Mech., 446, pp. 1–24, 2001.

37. U. Piomelli and E. Balaras “Wall-layer models for large-eddy simulations.” Annu. Rev. FluidMech. 34, pp. 349–374, 2002.

38. A. Scotti and U. Piomelli “Turbulence models in pulsating flows.” AIAA J., 40, pp. 537–540,2002.Also appeared as AIAA Paper 2001-0729, 2001.

39. U. Piomelli, E. Balaras, H. Pasinato, K.D. Squires and P.R. Spalart “The inner-outer layer inter-face in large-eddy simulations with wall-layer models.” Int. J. Heat Fluid Flow , 24, pp. 538-550,2003.Also appeared as “Interaction of the inner and outer layers in large-eddy simulations withwall-layer models” by U. Piomelli, E. Balaras, K.D. Squires and P.R. Spalart in Engineer-ing Turbulence Modeling and Experiments 5, eds. W. Rodi and N. Fueyo, (Elsevier, Amster-dam), pp. 307–316, 2002.

40. R. Broglia, A. Pascarelli and U. Piomelli “Large-eddy simulations of ducts with a free surface.”J. Fluid Mech., 484, pp. 223–253, 2003.

41. A. Dimas, B. Mowli and U. Piomelli “Large-eddy simulation of subcritical transition in anattachment-line boundary layer.” Comp. Math. with Appl., 46, pp. 571–590, 2003.

42. A. Keating, U. Piomelli, K. Bremhorst and S. Nesic “Large-eddy simulation of heat transferdownstream of a backward-facing step.” J. Turbulence 5, 2004.

43. A. Keating, U. Piomelli, E. Balaras, and H.-J. Kaltenbach “A priori and a posteriori tests ofinflow conditions for large-eddy simulation” Phys. Fluids, 16, pp. 4696–4712, 2004.

44. V. Ovchinnikov, U. Piomelli and M. M. Choudhari “Numerical simulations of boundary-layertransition induced by a cylinder wake.” J. Fluid Mech., 547, pp. 413–441, 2006.

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45. A. Silva Lopes, U. Piomelli and J. M. L. M. Palma “Large-eddy simulation of the flow in anS-duct.” J. of Turbulence, 7(11), pp. 1–24, 2006.

46. A. Keating and U. Piomelli “A dynamic stochastic forcing method as a wall-layer model for large-eddy simulation.” J. Turbulence, 7(12) pp. 1–24, 2006.

47. A. Keating, G. De Prisco and U. Piomelli. “Interface conditions for hybrid RANS/LES calcu-lations.” Int. J. Heat Fluid Flow 27, pp. 777–788, 2006.

48. S. Radhakrishnan, U. Piomelli, A. Keating and A. Silva Lopes. “Reynolds-Averaged andLarge-Eddy simulations of turbulent non-equilibrium flows.” J. of Turbulence, 7(63) pp. 1–20,2006.

49. G. De Prisco, U. Piomelli and A. Keating. “Improved turbulence generation techniques forhybrid RANS/LES calculations.” J. Turbulence, 9(5) pp. 1–20, 2007.

50. S. Radhakrishnan, U. Piomelli. “Large-eddy simulation of oscillating boundary layers: modelcomparison and validation.” J. Geophys. Res.–Oceans, 113(C02022), pp. 1–14, 2008.

51. U. Piomelli. “Wall-layer models for large-eddy simulations.” Prog. Aerosp. Sci., 44(6), pp. 437–446, 2008.Also appeared as AIAA Paper 2008-0603.

52. S. Radhakrishnan, U. Piomelli and A. Keating. “Wall-modeled large-eddy simulations of flowswith curvature and mild separation,” ASME J. Fluids Eng., 130 101203-1–8, 2008.

53. V. Ovchinnikov, M. M. Choudhari and U. Piomelli. “Numerical simulations of boundary-layerbypass transition due to high-amplitude free-stream turbulence,” J. Fluid Mech., 613, pp. 135–169, 2008.

54. M. Vanella, U. Piomelli, and E. Balaras. “Effect of grid discontinuities in large-eddy simulationstatistics and flow fields,” J. Turbul., 9(32), pp. 1–23, 2008.

55. U. Piomelli and C. Scalo. “Subgrid-scale modelling in relaminarizing flows.” Fluid Dyn. Res.,42 045510 (15 pages), 2010.Also appeared as “Large-eddy simulations of relaminarizing flows,” in Proc. 17th Annual Confer-ence of the CFD Society of Canada, no. CFDSC2009-1A4, pp. 1–10, 2009.

56. R. Y . Cao, T. St. Amand, M. D . Ford, U. Piomelli and C. D. Funk. “The Murine AngiotensinII-Induced Abdominal Aortic Aneurysm Model: Rupture Risk and Inflammatory ProgressionPatterns,” Frontiers in Pharmacology, 1(9), pp. 1–7, 2010.

57. M. Li, S. Radhakrishnan, U. Piomelli and W. R. Geyer. “Large-eddy simulation of the tidal-cycle variations of an estuarine boundary layer,” J. Geophys. Res.-Oceans, 115(C08003), pp. 1–18,2010.

58. A. Pinelli, I. Z. Naqavi, U. Piomelli and J. Favier. “Immersed Boundary Methods for generalfinite-difference and finite-volume Navier-Stokes solvers,” J. Comput. Phys., 229, pp. 90739091,2010.Also appeared as “Immersed boundary method for generalised finite volume and finite differenceNavier-Stokes solvers.” In Proc. ASME 2010 3rd Joint US-European Fluids Eng. Summer Meeting& 8th International Conf. on Nanochannels, Microchannels, and Minichannels, number FEDSM-ICNMM2010-30529, 2010.

59. I. Z. Naqavi and U. Piomelli. “Large eddy simulation of boundary layers with embedded spanwisevortices.” Int. J. Comput. Fluid Dyn., 24, pp. 467477, 2010.

60. H. Raiesi, U. Piomelli and A. Pollard. “Evaluation of Turbulence Models Using Direct Numericaland Large-Eddy Simulation Data.” ASME J. Fluids Eng., 133, pp. 0212203110, 2011.Also appeared in Proc. ASME 2010 3rd Joint US-European Fluids Eng. Summer Meeting &8th International Conf. on Nanochannels, Microchannels, and Minichannels, number FEDSM-ICNMM2010-31094, 2010.

61. M. Omidyeganeh and U. Piomelli. “Large-eddy simulation of the flow over two-dimensionaldunes in steady unidirectional flow.” J. Turbulence, 12(N42), pp. 1–31, 2011.

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62. M. D. Ford, A. T. Black, R. Y. Cao, C. D. Funk and U. Piomelli. “Hemodynamics of MouseAbdominal Aortic Aneurysm.” J. Biomech. Eng., 133(12), pp. 12100819, 2011.

63. J. Favier, A. Pinelli and U. Piomelli. “On the hydrodynamic influence of tubercles on whaleflippers.” C. R. Mecanique 340, pp. 107–114, 2012. doi:10.1016/j.crme.2011.11.004.

64. C. Scalo, U. Piomelli and L. Boegman. “Large-eddy simulation of oxygen transfer to organic sed-iment beds.” J. Geophys. Res.-Oceans, 117, C06005, pp. 1–17, 2012. doi:10.1029/2011JC007289.

65. G. Lee, C. Scalo and U. Piomelli. “A simple technique for the visualization of eddy kine-matics in turbulent flows.” Int. J. Comput. Fluid Dyn., 26(4), pp. 263274, 2012. doi:10.1080/10618562.2012.693605.

66. C. Scalo, U. Piomelli and L. Boegman. “Mass transport mechanisms at high Schmidt num-bers from a turbulent flow to underlying weakly absorbing sediment layers.” Phys. Flu-ids, 117, pp. C06005-1–17, 2012. doi: 10.1063/1.4739064.

67. M. D. Ford and U. Piomelli. “Exploring high frequency temporal fluctuations in the termi-nal aneurysm of the basilar bifurcation.” J. Biomech. Eng., 134, pp. 091003110, 2012. doi:10.1115/1.4007279.

68. M. Omidyeganeh, U. Piomelli. “Large-eddy simulation of three-dimensional dunes in a steady,unidirectional flow. Part 1: Turbulence statistics.” J. Fluid Mech. 721, pp. 454–483, 2013.doi:10.1017/jfm.2013.36.

69. C. Scalo, L. Boegman and U. Piomelli. “Large-eddy simulation and low-order modeling ofsediment oxygen uptake in a transitional oscillatory flow.” J. Geophys. Res.-Oceans, 118, pp. 1-14, 2013. doi: 10.1002/jgrc.20113.

70. C. Scalo, U. Piomelli and L. Boegman. “Self-similar decay and mixing of a high-Schmidt-numberpassive scalar in an oscillating boundary layer in the intermittently turbulent regime.” J. FluidMech., 726, pp. 728–750, 2013. doi:10.1017/jfm.2013.228.

71. A. Rouhi, U. Piomelli and P. Vlachos. “Numerical investigation of pulsatile flow in endovascularstents.” Phys. Fluids, 25 091905-1–18, 2013. doi: 10.1063/1.4821618.

72. M. Omidyeganeh, U. Piomelli, K. T. Christensen and J. Best. “Large-eddy simulation ofinteracting barchan dunes in a steady, unidirectional flow.” J. Geophys. Res.: Earth Surface,118, pp. 1–16, 2013. doi: 10.1002/jgrf.20149.

73. U. Piomelli and J. Yuan. “Numerical simulations of spatially developing, accelerating boundarylayers.” Phys. Fluids, 25 01304-1–21, 2013. doi: 10.1063/1.4825033.

74. M. Omidyeganeh and U. Piomelli. “Large-eddy simulation of three-dimensional dunes in asteady, unidirectional flow. Part 2: Flow structures.” J. Fluid Mech., 734, pp. 509–534, 2013.doi: 10.1017/jfm.2013.499.

75. J. Yuan and U. Piomelli. “Numerical simulations of sink-flow boundary layers over rough sur-faces.” Phys. Fluids, 26, 015113-1–28, 2014. doi: 10.1063/1.4862672.

76. R. Banyassady and U. Piomelli. “Turbulent plane wall-jets over smooth and rough surfaces.”J. Turbulence, 15(3), pp. 186–207, 2014. doi: 10.1080/14685248.2014.888492.

77. J. Yuan and U. Piomelli. “Estimation and prediction of the roughness function on realisticsurfaces.” J. Turbulence, 15(6), pp. 350–365, 2014.

78. U. Piomelli. “Large-eddy simulations in 2030 and beyond.” Phil. Trans. R. Soc. A, 372(20130320),pp. 1–13, 2014.

79. W. Wu and U. Piomelli. “Large-eddy simulation of impinging jets with embedded azimuthalvortices.” J. Turbulence, 16(1), pp. 44–66, 2014. doi: 10.1080/14685248.2014.957383.

80. J. Yuan and U. Piomelli. “Roughness effects on the energy budgets in near-wall turbulence: adirect numerical simulation study”. J. Fluid Mech., 760, pp. R1112, 2014.

81. A. Skillen, A. Revell, A. Pinelli, U. Piomelli and J. Favier. “Flow over a wing with leading-edgeundulations.” AIAA J., 52(2), pp. 464–472, 2015. doi: 10.2514/1.J053142.

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82. U. Piomelli, A. Rouhi, and B. J. Geurts. “A grid-independent length scale for large-eddysimulations.” J. Fluid Mech., 766, pp. 499–527, 2015. doi: 10.1017/jfm.2015.29.

83. R. Banyassady and U. Piomelli. “Interaction of inner and outer layers in plane and radialwall-jets.” J. Turbulence, 16(5), pp. 460483, 2015. doi: 10.1080/14685248.2015.1008008.

84. A. Jabbari, L. Boegman, and U. Piomelli. ”Evaluation of the inertial dissipation method withinboundary layers using numerical simulations.” Geophys. Res. Lett., 42, pp. ‘1504-1511, 2015.doi: 10.1002/2015GL063147.

85. A. Silva Lopes, J.M.L.M. Palma and U. Piomelli. “On the Determination of Effective Rough-ness of Surfaces with Vegetation Patches.” Bou. Lay. Meteor., 156, pp. 113–131, 2015. doi:10.1007/s10546-015-0022-z.

86. J. Yuan, U. Piomelli. “Numerical simulation of a spatially developing accelerating boundarylayer over roughness.” J. Fluid Mech., 780, pp. 192–214, 2015. doi: 10.1017/jfm.2015.437.

87. W. Wu, U. Piomelli. “Reynolds-averaged and wall-modelled large-eddy simulations of impingingjets with embedded azimuthal vortices.” European J. Mech./B Fluids, 55, part 2, pp. 348–359,2016. doi: 10.1016/j.euromechflu.2015.06.008.

88. W. Wu, R. Banyassady, and U. Piomelli. “Large-eddy simulation of impinging jets on smoothand rough surfaces.” J. Turbul., 17(7), PP. 1–23, 2016.

89. A. Rouhi, U. Piomelli, and B. J. Geurts. “A dynamic subfilter-scale stress model for large eddysimulations.” Phys. Rev. Fluids, 1(4), pp. 044401–1–26, 2016.

90. W. Wu, G. Soligo, C. Marchioli, A. Soldati and U.Piomelli. ”Particle resuspension by aperiodically-forced impinging jet.” J. Fluid Mech., 820, pp. 284–311, 2017.

91. R. Dutta, J. Nicolle, A.-M. Giroux and U. Piomelli. “Evaluation of turbulence models in rough-wall boundary layers for hydroelectric applications.” Int. J. Fluid Mach. Sys., 10(3), pp. 228-239,2017.

92. I. Rodrıguez, O. Lehmkuhl, U. Piomelli, J. Chiva, R. Borell, A. Oliva. “LES-based study ofthe roughness effects on the wake of a circular cylinder from subcritical to transcritical Reynoldsnumbers.” Flow, Turb. Combust., 99, pp. 739–763, 2017.

93. W. Wu and U. Piomelli. “Effects of surface roughness on a separating turbulent boundary layer.”J. Fluid Mech., 841, pp. 552–580, 2018.

94. U. Piomelli. “Recent advances in the numerical simulation of rough-wall boundary layers”. Inpress, Phys. Chem. Earth, 2019. Available online at https://doi.org/10.1016/j.pce.2018.10.005.

95. M. Mellati Nokhandan, U. Piomelli and M. Omidyeganeh. “Large-Eddy and Wall-ModelledSimulations of Turbulent Flow over Two-Dimensional River Dunes.” In press, Phys. Chem. Earth,2019. Available online at https://doi.org/10.1016/j.pce.2018.11.004.

96. B. Geurts, A. Rouhi and U. Piomelli. “Recent progress on reliability assessmentof large-eddy eddy simulation.” In press, J. Fluid Structures. Available online athttps://doi.org/10.1016/j.jfluidstructs.2019.03.008, 2019.

97. O. Lehmkuhl, U. Piomelli and G. Houzeaux. “On the extension of the integral length-scaleapproximation model to complex geometries.” Accepted for publication, Int. J. Heat Fluid Flow,2019.

98. W. Wu, U. Piomelli and J. Yuan. “Turbulence statistics in rotating channel flows with roughwalls.” Submitted to Int. J. Heat Fluid Flow, 2019.

B. Books edited

1. Engineering applications of large eddy simulations–1993, eds. S. A. Ragab and U. Piomelli,(ASME) 1993.

2. Introduction to turbulence modelling, eds. U. Piomelli, C. Benocci and J. van Beeck, (Von KarmanInstitute, Rhode-Saint-Genese), 2004.

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3. Large-eddy simulations and related techniques, eds. C. Benocci, J. van Beeck and U. Piomelli,(Von Karman Institute, Rhode-Saint-Genese), 2006.

4. Large-eddy simulations and related techniques, eds. U. Piomelli, C. Benocci, J. van Beeck, (VonKarman Institute, Rhode-Saint-Genese), 2010.



7. Large-eddy simulations and related techniques, eds. U. Piomelli, J. van Beeck, (Von KarmanInstitute, Rhode-Saint-Genese), 2018.

C. Chapters in books

1. U. Piomelli “Applications of large-eddy simulation in engineering – An overview.” (Invited re-view article). In Large Eddy Simulation of Complex Engineering and Geophysical Flows, eds. B.Galperin and S. A. Orszag, (Cambridge University Press, Cambridge), pp. 119–137, 1993.

2. T. A. Zang and U. Piomelli “Large-eddy simulation of transitional flows.” In Large Eddy Simu-lation of Complex Engineering and Geophysical Flows, eds. B. Galperin and S. A. Orszag, (Cam-bridge University Press, Cambridge), pp. 209–227, 1993.Also appeared in International Workshop on “Large Eddy Simulation. . . Where do we stand?”St. Petersburg, Florida, December 19–21, 1990.

3. U. Piomelli and J. R. Chasnov “Large-eddy simulations: theory and applications.” In Transitionand turbulence modelling, eds. D. Henningson, M. Hallback, H. Alfreddson and A. Johansson,(Kluwer Academic Publishers, Dordrecht), pp. 269–336, 1996.

4. U. Piomelli “Large-eddy and direct simulation of turbulent flows.” In Introduction to turbulencemodelling, ed. M. Manna, (Von Karman Institute, Rhode-Saint-Genese), 1997.

5. U. Piomelli “Large-eddy simulations: where we stand.” In Advances in DNS/LES, eds. C. Liuand Z. Liu, (Greyden Press, Columbus), pp. 93–104, 1997.

6. U. Piomelli “Turbulence modeling requirements.” In Introduction to turbulence modelling, ed. D.Olivari, (Von Karman Institute, Rhode-Saint-Genese), 1998.

7. U. Piomelli “Large-eddy simulation: theory and applications.” In Introduction to turbulencemodelling, ed. D. Olivari, (Von Karman Institute, Rhode-Saint-Genese), 1998.

8. U. Piomelli “Large-eddy and direct simulation of turbulent flows.” In Introduction to turbulencemodelling, ed. J. van Beeck, (Von Karman Institute, Rhode-Saint-Genese), 2000.

9. U. Piomelli, A. Scotti and E. Balaras. “Large-eddy simulations: from desktop to supercomputer.”In Vector and Parallel Processing - VECPAR’2000. Fourth International Conference on Vectorand Parallel Processing. Porto, Portugal, June 2000. Invited Talks and Selected Papers, eds. J.M. L. M. Palma, J. Dongarra and V. Hernandez, (Springer, Berlin), pp. 554–582, 2001.

10. G. V. Diurno, E. Balaras and U. Piomelli. “Wall-layer models for LES of separated flows.” InModern simulation strategies for turbulent flows, ed. B. Geurts, (Philadelphia, Edwards), pp. 207–222, 2001.

11. A. Pascarelli, F. S. Marra, U. Piomelli “Large-Eddy Simulation of the Flow over a Wall–MountedFence.” In Direct and Large-Eddy Simulation IV, ed. B.J. Geurts, R. Friedrich and O. Metais,(Kluwer, Dordrecht), pp. 419–426, 2001.

12. U. Piomelli and E. Balaras “Numerical simulations using the immersed boundary technique.”In DNS/LES Progress and Challenges, eds. C. Liu, L. Sakell and T. Beutner, (Greyden Press,Columbus), pp. 105–116, 2001.

13. U. Piomelli “Large-eddy and direct simulation of turbulent flows.” In Introduction to turbulencemodelling, ed. J. van Beeck, (Von Karman Institute, Rhode-Saint-Genese), 2002.

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14. U. Piomelli “Large-eddy and direct simulation of turbulent flows.” In Introduction to turbulencemodelling, eds. U. Piomelli, C. Benocci and J. van Beeck, (Von Karman Institute, Rhode-Saint-Genese), 2004.

15. A. Silva Lopes, U. Piomelli, and J. M. L. M. Palma. “Large-eddy simulation of a flow withcurvatures using wall-layer models.” In Advances in turbulence X, eds. H. I. Andersson and P.-A.Krogstad (Kluwer, Dordrecht), pp. 249–252, 2004.

16. A. Silva Lopes, U. Piomelli, and J. M. L. M. Palma “Large-eddy simulation of a flow with multiplestreamwise curvatures.” In Direct and Large-Eddy Simulation V, eds. R. Friedrich, B.J. Geurtsand O. Metais (Kluwer, Dordrecht), pp. , 2004.

17. A. Keating, G. De Prisco, U. Piomelli, E. Balaras “Interface conditions for hybrid RANS/LEScalculations,” In Engineering Turbulence Modeling and Experiments 6, eds. W. Rodi and M.Mulas, (Elsevier, Amsterdam), pp. 349–358, 2005.

18. A. Cubero and U. Piomelli “Large-eddy simulations of channel flows with variable filter-width-to-grid-size ratios.” In Direct and Large-Eddy Simulation VI, eds. E. Lamballais, R. Friedrich, B.J. Geurts, and O. Metais, (Kluwer, Dordrecht), 2006.

19. G. De Prisco, A. Keating, U. Piomelli and E. Balaras “Large-eddy simulation of acceleratingboundary layers” In Progress in Turbulence II, eds. Oberlack, M.; Khujadze, G.; Guenther, S.;Weller, T.; Frewer, M.; Peinke, J.; Barth, S., pp. 137–144, (Springer, Berlin), 2007.

20. U. Piomelli, S. Radhakrishnan, L. Zhong, and M. Li “Wall-layer models for large-eddy simula-tions of high Reynolds number non-equilibrium flows.” In Advances in Turbulence XI, eds. Palma,J. M. L. M. and Silva Lopes, A., pp. 47–54, (Springer, Berlin), 2007.

21. U. Piomelli, S. Radhakrishnan, and G. De Prisco. “Turbulent eddies in the RANS/LES tran-sition region.” In Advances in Hybrid RANS-LES Modelling, volume 97 of Notes on Numer-ical Fluid Mechanics and Multidisciplinary Design, eds. S.-H. Peng and W. Haase, pp. 21–36,(Springer, Berlin), 2008.

22. U. Piomelli and C. Scalo. “Large-eddy simulations of relaminarization due to freestream ac-celeration.” In Seventh IUTAM Symposium on Laminar-Turbulent Transition, eds. P. Schlat-ter and D. Henningson, pp. 35–42, (Springer, Berlin) 2010.

23. U. Piomelli. “Wall-modeled LES: Present status and prospects.” In Direct and Large-EddySimulation VII, eds. V. Armenio, B. J. Geurts, and J. Frohlich, pp. 1–10, (Springer, Berlin) 2010.

24. U. Piomelli “Large-eddy simulation of turbulent flows. Part I: Introduction.” In Introductionto turbulence modelling, eds. U. Piomelli, C. Benocci and J. van Beeck, (Von Karman Institute,Rhode-Saint-Genese), 2010.




28. U. Piomelli “Large-eddy simulation of turbulent flows. Part I: Introduction.” In Introduction toturbulence modelling, eds. U. Piomelli, and J. van Beeck, (Von Karman Institute, Rhode-Saint-Genese), 2018.

29. U. Piomelli “Large-eddy simulation of turbulent flows. Part II: Hybrid RANS/LES methods.” InIntroduction to turbulence modelling, eds. U. Piomelli, and J. van Beeck, (Von Karman Institute,Rhode-Saint-Genese), 2018.

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D. Monographs, reports and extension publications

1. V. Losito, C. de Nicola, and U. Piomelli “Predizione numerica della resistenza aerodinamica delleautovetture.” Istituto di Aerodinamica, Universita degli Studi di Napoli, Naples, Italy, 1979.

2. P. Bradshaw, N. N. Mansour, and U. Piomelli “On local approximations of the pressure-strainterm in turbulence models.” In Studying Turbulence Using Numerical Databases – Proceedings ofthe 1987 Summer Program. pp. 159-164, Center for Turbulence Research, Stanford, California,1987.

3. U. Piomelli, J. H. Ferziger, and P. Moin “Models for large eddy simulation of turbulent channelflow including transpiration.” Department of Mechanical Engineering Report TF-32, StanfordUniversity, Stanford, California, 1987.

4. A. J. Faller, S.-T. Yang, and U. Piomelli “Instability of the KEB boundary layers.” Institute forPhysical Science and Technology, University of Maryland, College Park, Maryland, 1989.

5. U. Piomelli “Large-eddy simulation of turbulent flows.” TAM Report No. 767, Department ofTheoretical and Applied Mechanics, The University of Illinois at Urbana-Champaign, 1994.

E. Book reviews, other articles and notes

1. U. Piomelli “Review of Hydrodynamic and magneto-hydrodynamic turbulence flows by A.Yoshizawa.” AIAA J. 38 p. 548, 2000.

2. U. Piomelli “Review of Large-Eddy Simulations for Incompressible Flows: an Introduction byPierre Sagaut.” J. Turbul. 2, 2001.

3. U. Piomelli and M. M. Choudhari “Year-in-Review: Fluid Dynamics.” Aerospace Amer-ica, 43(12), December 2005, pp. 10–11 (2005).

4. M. M. Choudhari and U. Piomelli “Year-in-Review: Fluid Dynamics.” Aerospace Amer-ica, 44(12), December 2006, pp. 20–21 (2006).

5. F. Ladeinde, T. McLoughlin, M. M. Choudhari and U. Piomelli, “Year-in-Review: Fluid Dynam-ics.” Aerospace America, 45(12), December 2008, pp. 8–9 (2008).

F. Refereed conference proceedings

1. T. J. Akai and U. Piomelli. “Effect of upstream parallel flow on two-dimensional wind-tunneltests.” AIAA Paper 84-2153, 1984.

2. U. Piomelli, T. A. Zang, C. G. Speziale, and T. S. Lund. “Application of Renormalization GroupTheory to the large-eddy simulation of transitional boundary layers.”In Instability and Transition,eds. M.Y. Hussaini and R.G. Voigt (Springer-Verlag, New York), vol. 2, pp. 480–496, 1990.

3. H. Esmaili and U. Piomelli. “Large-eddy simulation of relaminarizing sink flow boundary layers.”In Near-Wall Turbulent Flows, eds. R. M. C. So, C. G. Speziale and B. E. Launder, (Elsevier,Amsterdam), pp. 287–296, 1993.

4. P. A. Chang, III, B. M. Abraham, and U. Piomelli. “Wavenumber-frequency characterizationof wall pressure fluctuations computed using turbulence simulations.” In Symp. Active/PassiveControl of Flow-Induced Vibration and Noise, eds. K. W. Wang, A. H. von Flotow, R. Soureshi,E. W. Hendricks and T. M. Farabee, (ASME), pp. 229–244, 1994.

5. U. Piomelli “Subgrid-scale models for large-eddy simulations. Part I: theory.” In Proc. 1994Workshop on Mathematical Modeling of Turbulent Flows, Tokyo, Japan, 1994.

6. U. Piomelli. “Subgrid-scale models for large-eddy simulations. Part II: applications.” Proc. 1994Workshop on Mathematical Modeling of Turbulent Flows, Tokyo, Japan, 1994.

7. K. D. Squires and U. Piomelli. “Dynamic modeling of rotating turbulence.” In Turbulent ShearFlows 9, eds. F. Durst, N. Kasagi, B. E. Launder, F. W. Schmidt and J. H. Whitelaw, (SpringerVerlag, New York), pp. 73–86, 1995.Also appeared as “Large-eddy simulation of rotating turbulence using the dynamic model” inProc. Ninth Symposium on Turbulent Shear Flows, Kyoto, Japan, August 16–18, 1993.

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8. P. I. Espina and U. Piomelli. “Validation of the NPARC code in supersonic base flows.” AIAAPaper No. 97-0032, 1997.

9. U. Piomelli. “Large-eddy simulation: present state and future directions.” Invited paper, AIAAPaper No. 98-0534, 1998.

10. P. I. Espina and U. Piomelli “Study of the gas jet in a close-coupled gas-metal atomizer.” AIAAPaper No. 98-0959, 1998.

11. P. I. Espina and U. Piomelli “Numerical simulation of the gas flow in gas-metal atomizers.”Proc. 1998 ASME Fluids Engineering Division Summer Meeting, FEDSM98-4901, (ASME) 1998.

12. P. I. Espina, S. D. Ridder, U. Piomelli, and F. S. Biancaniello. “Numerical simulation ofatomization gas flows.” 1998 Powder Metallurgy World Congress & Exhibition (EPMA) 1998.

13. U. Piomelli. “Recent developments in large-eddy simulation.” Invited paper, 3rd ASME/JSMEJoint Fluids Engineering Conference, FEDSM 99-7852 (ASME) 1999.

14. U. Piomelli, E. Balaras, K.D. Squires and P.R. Spalart. “Zonal approaches to wall-layer modelsfor large-eddy simulations.” AIAA Paper 2002-3083, 2002.

15. A. Silva Lopes, U. Piomelli, and J. M. L. M. Palma. “Large-eddy simulation of the flow in anS-duct.” AIAA Paper 2003-0964, 2003.

16. U. Piomelli, M. M. Choudhari, V. Ovchinnikov, and E. Balaras. “Numerical simulations ofwake/boundary-layer interactions.”AIAA Paper 2003-0975, 2003.

17. V. Ovchinnikov, U. Piomelli, and M. M. Choudhari. “Inflow Conditions for numerical simula-tions of bypass transition.” AIAA Paper 2004-0591, 2004.

18. A. Keating and U. Piomelli. “Synthetic Generation of Inflow Velocities for Large- Eddy Simula-tions.” AIAA Paper 2004-2547, 2004.

19. A. Silva Lopes, U. Piomelli, and J. M. L. M. Palma. “Large- Eddy Simulations of a Flow withStreamwise Curvature Changes.” AIAA Paper 2004-2549, 2004.

20. V. Ovchinnikov, U. Piomelli, and M.M. Choudhari. “Numerical Simulations of Boundary LayerBypass Transition with Leading Edge Effects.” In Proc. TSFP-4, Williamsburg, Virginia, June2005.

21. S. Radhakrishnan, A. Keating, U. Piomelli and A. Silva Lopes “Large-Eddy Simulations ofHigh Reynolds Number Flow over a Contoured Ramp” AIAA Paper 2006-0899, 2006.

22. G. De Prisco, A., Keating, and U. Piomelli “Large-eddy simulation of accelerating boundarylayers.” AIAA Paper 2007-0725, 2007.

23. M. Omidyeganeh and U. Piomelli. “Coherent structures in the flow over two-dimensionaldunes.” In Proc. 18th Annual Conf. CFD Soc. of Canada, 2010.

24. C. Scalo and U. Piomelli. “Grid requirements for large-eddy simulations of passive scalar trans-port at high Prandtl numbers.” In Proc. 18th Annual Conf. CFD Soc. of Canada, 2010.

25. U. Piomelli and V. Grazioso. “Direct numerical simulation of boundary layers subjected tofreestream acceleration.” In Proc. 18th Annual Conf. CFD Soc. of Canada, 2010.

26. H. Raiesi, A. Pollard and U. Piomelli. ’Direct numerical simulations of turbulent flow in squareand skewed ducts.” In Proc. 18th Annual Conf. CFD Soc. of Canada, 2010.

27. M. D. Ford, U. Piomelli, C. D. Funk, R. Y. Yao, and A. Pollard. “Numerical simulations ofthe intra-aneurysmal vortex shedding in induced mouse abdominal aortic aneurysms.” In Proc.ASME 2010 3rd Joint US-European Fluids Eng. Summer Meeting & 8th International Conf. onNanochannels, Microchannels, and Minichannels, number FEDSM-ICNMM2010-30529, 2010.

28. A. Pinelli, I. Z. Naqavi and U. Piomelli. “Immersed boundary method for generalised finitevolume and finite difference Navier-Stokes solvers.” In Proc. ASME 2010 3rd Joint US-EuropeanFluids Eng. Summer Meeting & 8th International Conf. on Nanochannels, Microchannels, andMinichannels, number FEDSM-ICNMM2010-30546, 2010.

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29. J. Yuan and U. Piomelli. “Large-eddy simulation of accelerating boundary layers over roughsurfaces.” Seventh International Symposium On Turbulence and Shear Flow Phenomena (TSFP-7), 2011.

30. M. Omidyeganeh and U. Piomelli. “Large Eddies in the Flow over Dunes.” Seventh Interna-tional Symposium On Turbulence and Shear Flow Phenomena (TSFP-7), 2011.

31. M. Omidyeganeh and U. Piomelli, “Large-Eddy Simulation of Turbulent Flow over Two-Dimensional River Dunes,” Coherent Flow Structures in Geophysical Flows at Earth’s Surface, Au-gust, 2011, Simon Fraser University, Canada.

32. C. Scalo, U. Piomelli and L. Boegman, “Large-eddy simulation of oxygen transfer to organicsediment beds,” Seventh International Symposium On Turbulence and Shear Flow Phenomena(TSFP-7), 2011.

33. C. Scalo, U. Piomelli and L. Boegman, “A study of sedimentary oxygen demand with large-eddy simulation: from largescale hydrodynamics to small-scale mixing,” The 15th InternationalWorkshop on Physical Processes in Natural Water, Burlington, Ontario (PPNW), (2011).

34. M. Omidyeganeh, U. Piomelli, K. T. Christensen, and J. L. Best. “Large-eddy simulationof flow over barchan dunes.” In V. Van Lancker and T. Garlan, editors, Fourth InternationalConference on Marine and River Dune Dynamics, pp. 191—198. VLIZ special publication number65, 2013.

35. U. Piomelli and M. Omidyeganeh. “Large-eddy simulations in dune-dynamics research.” InV. Van Lancker and T. Garlan, editors, Fourth International Conference on Marine and RiverDune Dynamics, pp. 15—22. VLIZ special publication number 65, 2013.

36. J. Yuan and U. Piomelli. “Large-eddy and Direct Numerical Simulations of Equilibrium Accel-erating Turbulent Boundary Layers Over Rough Surfaces.” CFD2013–21st Annual Meeting of theCFD Society of Canada, Sherbrooke (QC), May 6–9, 2013. Awarded 2nd place in the Stu-dent Paper Competition.

37. R. Banyassady and U. Piomelli. “Turbulent plane wall jets over rough surfaces” CFD2013–21stAnnual Meeting of the CFD Society of Canada, Sherbrooke (QC), May 6–9, 2013.

38. J. Yuan and U. Piomelli. “Large-eddy and direct simulations of sink flows over rough walls.”Eighth International Symposium On Turbulence and Shear Flow Phenomena (TSFP-8), 2013.

39. A. Skillen, A. Revell, J. Favier, A. Pinelli and U. Piomelli. “Investigation of wing stall delayeffect due to an undulating leading edge: An LES study.” Eighth International Symposium OnTurbulence and Shear Flow Phenomena (TSFP-8), 2013.

40. J. Yuan, J. Nicolle, U. Piomelli, and A.-M. Giroux. “Modelling roughness and acceleration effectswith application to the flow in a hydraulic turbine”. Paper 2536013, 27th IAHR Symposium,2014.

41. U. Piomelli, A. Rouhi, and B. J. Geurts. A physics-based length-scale for large-eddy simulations.In M. A. Leschziner, editor, Proc. 10th Int. Symp. Eng. Turbulence Modelling and Measurements- ETMM10. ERCOFTAC, 2014.

42. P. Mottaghian, J. Yuan and U. Piomelli. Boundary layer separation under strong adversepressure gradient over smooth and rough walls. ERCOFTAC Symposium on Direct and Large-Eddy Simulations, DLES10, Limassol, Cyprus, May 20, 2015.

43. R. Dutta, J. Nicolle, A.-M. Giroux and U. Piomelli. Evaluation of turbulence models on roughenedturbine blades. 28th IAHR symposium on Hydraulic Machinery and Systems (IAHR2016), R. F.Patella, ed., vol. 49 of IOP Conference Series: Earth and Environmental Science (EES), Instituteof Physics, IOP Publishing, pp. 062007–1–10, 2016.

44. U. Piomelli, W. Wu and J. Yuan. Effect of roughness on wall-bounded flows subjected to spanwiserotation. Proc. 12th Int. ERCOFTAC Symp. Eng. Turbulence Modelling and Measurements,Montpellier, France, 26-28 September 2018.

45. O. Lehmkuhl, U. Piomelli, G. Houzeaux. On the extension of the Integral Length-Scale Approxi-mation model to complex geometries. Proc. 12th Int. ERCOFTAC Symp. Eng. Turbulence Mod-elling and Measurements, Montpellier, France, 26-28 September 2018.

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G. Invited and keynote talks

1. Subgrid-scale models for large-eddy simulations. Part I: theory. Invited talk delivered at the 1994Workshop on Mathematical Modelling of Turbulent Flows, Tokyo, Japan, July 1994.

2. Subgrid-scale models for large-eddy simulations. Part II: applications. Invited talk delivered atthe 1994 Workshop on Mathematical Modelling of Turbulent Flows, Tokyo, Japan, July 1994.

3. Large-eddy simulations: theory and applications. Invited lectures (2.5 hours) presented at theERCOFTAC Summer School on Turbulence and Transition modeling, Department of Mechanics,Royal Institute of Technology, Stockholm, June 1995.

4. Subgrid-scale models of non-equilibrium flows. Invited talk delivered at the International Sympo-sium on Mathematical Modelling of Turbulent Flows, Tokyo, Japan, December 1995.

5. DNS and LES, basic principles, current trends, expectations. Invited lectures (2.5 hours) deliveredat the von Karman Institute 1996–1997 Lecture Series on “Introduction to turbulence modelling”,Rhode-Saint-Genese, Belgium, March 1997.

6. Application of LES to engineering problems. Invited lecture (1.25 hours) delivered at the vonKarman Institute 1996–1997 Lecture Series on “Introduction to turbulence modelling”, Rhode-Saint-Genese, Belgium, March 1997.

7. Turbulence modeling requirements. Invited lecture (1.25 hours) delivered at the von KarmanInstitute 1997–1998 Lecture Series “Introduction to turbulence modelling”, Rhode-Saint-Genese,Belgium, March 1998.

8. Large-eddy simulation: theory and applications. Invited lectures (2.5 hours) delivered at the vonKarman Institute 1997–1998 Lecture Series “Introduction to turbulence modelling”, Rhode-Saint-Genese, Belgium, March 1998.

9. Large-eddy simulation: present state and future directions. Invited talk presented at the 36thAerospace Sciences Meeting and Exhibit, Reno, Nevada, January 1998.Also presented at the 1st Symp. on Marine Applications of CFD, Vienna, Virginia, May 1998.

10. Large-eddy simulation: theory and applications. Invited lectures (3 hours) delivered at the In-ternational School in Applied Mathematics “The Mathematical Approach to Turbulence: Numer-ical and Analytical Techniques”, Certosa di Pontignano, Italy, June 1998.

11. Recent developments in large-eddy simulation. U. Piomelli. Invited paper, presented at the 3rdASME/JSME Joint Fluids Engineering Conference, San Francisco, California, July 1999.

12. DNS and LES, basic principles, current trends, expectations. Invited lectures (2.5 hours) deliveredat the von Karman Institute 1999–2000 Lecture Series on “Introduction to turbulence modelling”,Rhode-Saint-Genese, Belgium, March 2000.

13. Application of LES to engineering problems. Invited lecture (1.25 hours) delivered at the vonKarman Institute 1999–2000 Lecture Series on “Introduction to turbulence modelling”, Rhode-Saint-Genese, Belgium, March 2000.

14. Large-eddy simulations: from desktop to supercomputer. Invited paper presented at the Vectorand Parallel Processing - VECPAR 2000. Fourth International Conference. Porto (Portugal),June 2000.

15. An introduction to direct and large-eddy simulations. Invited short course (6 hours) delivered atCFD2001, 9th Annual Conference of the CFD Society of Canada, Kitchener, Canada, May 2001.

16. Direct and large-eddy simulations: theory and applications. Invited short course (5 hours) deliv-ered at INSEAN, Rome, Italy, June 2001.

17. Numerical simulations using the immersed boundary method. Invited paper presented at the ThirdAFOSR International Conference on Direct Numerical Simulation and Large Eddy Simulation,Arlington, Texas, August 2001.

18. An introduction to direct and large-eddy simulations. Invited short course (6 hours) deliveredat von Karman Institute 2001–2002 Lecture Series on “Introduction to turbulence modelling”,Rhode-Saint-Genese, Belgium, March 2002.

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19. Numerical simulations of wake-induced transition in flat-plate boundary layers. Keynote lecturedelivered at the IUTAM Symposium on Unsteady Separated Flows, Toulouse, France, April 2002.

20. Dynamic and scale-similar subfilter-scale models. Invited talk delivered at the NCAR Workshopon Subfilter-Scale Closures, Boulder, Colorado, August 2002.

21. Large-eddy simulations: theory, applications and advanced topics. AIAA Professional Develop-ment Course, 41st Aerospace Sciences Meeting and Exhibit, Reno, Nevada, January 2003.

22. An introduction to direct and large-eddy simulations. Invited short course (6 hours) deliveredat von Karman Institute 2003–2004 Lecture Series on “Introduction to turbulence modelling”,Rhode-Saint-Genese, Belgium, March 2004.

23. Large-eddy simulations: theory, applications and advanced topics. AIAA Professional Develop-ment Course, 34th AIAA Fluid Dynamics Conference and Exhibit, Portland, Oregon, June 2004.

24. Interface conditions for hybrid RANS/LES simulations. Keynote lecture delivered at the Cen-ter for Environmental and Applied Fluid Mechanics 2005 Research Symposium, Johns Hop-kins University, Baltimore, Maryland, May 2005.

25. Modeling the turbulent wall layer at high Reynolds numbers. Invited lecture delivered at the Centerfor Nonlinear Studies Workshop on Multi-Scale Interactions in Turbulent Flows, Santa Fe, NewMexico, July 2005.

26. Large-eddy simulations of accelerating boundary layers. Invited lecture delivered at the iTi Con-ference on Turbulence, Bad Zwischenhan, Germany, September 2005.

27. Large-eddy simulations: theory, applications and advanced topics. AIAA Professional De-velopment Course, 44th AIAA Aerospace Sciences Meeting and Exhibit, Reno, Nevada, Jan-uary 2006.

28. Large-eddy simulations of turbulent flows. Invited short course (9 hours) delivered at von KarmanInstitute 2005–2006 Lecture Series on “Large-eddy simulations and related techniques”, Rhode-Saint-Genese, Belgium, March 2006.

29. Turbulent eddies in the RANS/LES transition region. Invited lecture delivered at the SecondSymposium on Hybrid RANS-LES Methods, Dassia, Greece, June 2007.

30. Wall-layer models for LES of high Reynolds number, non-equilibrium flows. Invited lecture deliv-ered at the 11th European Turbulence Conference, Porto, Portugal, June 2007.

31. Large-eddy simulations: theory, applications and advanced topics. AIAA Professional De-velopment Course, 46th AIAA Aerospace Sciences Meeting and Exhibit, Reno, Nevada, Jan-uary 2008.

32. Wall-layer models for LES. Invited lecture delivered at the 46th AIAA Aerospace Sciences Meetingand Exhibit, Reno, Nevada, January 2008.

33. Effect of local grid refinement on LES. Invited lecture delivered at the 7th International ERCOF-TAC Symposium on Engineering Turbulence Modelling and Measurements, Limassol, Cyprus,June 2008.

34. Wall-modeled LES: Present status and prospects. Invited lecture delivered at the 7th ERCOFTACWorkshop on Direct and Large-Eddy Simulations, Trieste, Italy, September 2008.

35. Large-eddy simulations of relaminarization due to freestream acceleration. Invited lecture de-livered at the 7th IUTAM Symposium on Laminar-Turbulent Transition, Stockholm, Swe-den, June 2009.

36. Large-eddy simulations of turbulent flows. Invited short course (9 hours) delivered at von KarmanInstitute 2009–2010 Lecture Series on “Large-eddy simulations and related techniques”, Rhode-Saint-Genese, Belgium, February 2010.

37. Boundary layers in favourable pressure gradients. Invited talk delivered at the 65th Annual Meet-ing of the American Physical Society/Division of Fluid Dynamics, San Diego, California, Novem-ber 2012.

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38. Large-eddy simulations in dune-dynamics research. Invited talk delivered at MARID 4, Marineand River Dune Dynamics, Bruges, Belgium, April 2013.

39. Large-eddy and direct simulations of sink flows over rough walls. Invited lecture delivered atthe 8th International Symposium on Turbulence and Shear Flow Phenomena (TSFP-8), Poitiers,France, August 2013.

40. Large-eddy simulations of turbulent flows. Invited short course (9 hours) delivered at von KarmanInstitute 2013–2014 Lecture Series on “Large-eddy simulations and related techniques”, Rhode-Saint-Genese, Belgium, May 2014.

41. Large-eddy simulations of turbulent flows. Invited short course (13.5 hours) delivered at vonKarman Institute 2015–2016 Lecture Series on “Large-eddy simulations and related techniques”,Rhode-Saint-Genese, Belgium, May 2016.

42. How numerical simulations can help understand roughness. Keynote lecture delivered at the 11thSymposium on Direct and Large-Eddy Simulations (DLES11), Pisa, Italy, May 2017.

43. Large-eddy simulations of turbulent flows. Invited short course (13.5 hours) delivered at vonKarman Institute 2017–2018 Lecture Series on “Large-eddy simulations and related techniques”,Rhode-Saint-Genese, Belgium, May 2018.

44. Numerical Simulations of Flows over Rough Surfaces Keynote lecture delivered at CFDSC18-Annual meeting of the CFD Society of Canada, Winnipeg, MB, June 2018.

45. The good, the bad, and the beautiful: Leonardo’s studies of turbulence.

(a) 2019 Adjeleian Lecture, Carleton University, Ottawa, ON, April 2019.

(b) Keynote lecture delivered at CANCAM 2019, 27th Canadian Congress of Applied Mechanics,Universite de Sherbrooke, May 2019.

H. Contributed talks

1. Numerical evaluation of subgrid-scale turbulence models. Presented at the 38th Annual Meetingof the American Physical Society–Division of Fluid Dynamics, Tucson, Arizona, November 1985.

2. New models for the large eddy simulation of turbulent channel flows. Presented at the 39thAnnual Meeting of the American Physical Society–Division of Fluid Dynamics, Columbus, Ohio,November 1986.

3. Model consistency in large eddy simulations of channel flows. Presented at the AIAA 19th FluidDynamics, Plasma Dynamics and Lasers Conference, Honolulu, Hawaii, June 1987.

4. Wall-layer models for large eddy simulations. Presented at the 40th Annual Meeting of the Amer-ican Physical Society–Division of Fluid Dynamics, Eugene, Oregon, November 1987.

5. On the validity of Taylor’s hypothesis for wall-bounded flows. Presented at the 41st Annual Meet-ing of the American Physical Society–Division of Fluid Dynamics, Buffalo, New York, Novem-ber 1988.

6. Large eddy simulation of the flow in a transpired channel. Presented at the AIAA 27th AerospaceMeeting, Reno, Nevada, January 1989.

7. Large-eddy simulation of transitional channel flow. Presented at the IMACS 1st InternationalConference on Computational Physics, Boulder, Colorado, June 1990.

8. On the large-eddy simulation of transitional wall-bounded flows. Presented at the 42nd AnnualMeeting of the American Physical Society–Division of Fluid Dynamics, Palo Alto, California,November 1989.

9. A dynamic subgrid-scale eddy viscosity model. Presented at the 43rd Annual Meeting of theAmerican Physical Society–Division of Fluid Dynamics, Ithaca, New York, November 1990.

10. Large-eddy simulation of detuned transition in plane channel flow. Presented at the 4th Interna-tional Symposium on Computational Fluid Dynamics, Davis, California, September 9–12, 1991.

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11. Local averaging of the dynamic subgrid-scale stress model. Presented at the 44th Annual Meetingof the American Physical Society–Division of Fluid Dynamics, Scottsdale, Arizona, November1991.

12. Reynolds stress and vorticity in turbulent wall flows. Presented at the Fourth European TurbulenceConference, Delft, The Netherlands, July 1992.

13. High Reynolds number calculations using the dynamic subgrid-scale stress model. Presented at the45th Annual Meeting of the American Physical Society–Division of Fluid Dynamics, Tallahassee,Florida, November 1992.

14. Subgrid-scale modeling of non-equilibrium flows. Presented at the Workshop on Non-equilibriumturbulence, Arizona State University, Tempe, Arizona, March 10–12, 1993.

15. Large-eddy simulation of relaminarizing sink flow boundary layers. Presented at the Int. Conf.on Near-Wall Turbulent Flows, Tempe, Arizona, U.S.A., March 15–18, 1993.

16. Applications of the localized dynamic subgrid-scale stress model. Presented at the 46th AnnualMeeting of the American Physical Society–Division of Fluid Dynamics, Albuquerque, New Mexico,November 1993.

17. Large-eddy simulation of rotating channel flows using a localized dynamic model. Presented at theAGARD/FDP 74th Meeting and Symposium on Application of Direct and Large Eddy Simulationto Transition and Turbulence, Chania, Greece, 18-21 April 1994.

18. Large-eddy simulation of the flow behind an array of vortex generators. Presented at the ER-COFTAC Workshop on Large Eddy Simulation, Rome, Italy, July 1994, and at the Fifth Euro-pean Turbulence Conference, Siena, Italy, July 1994.

19. Subgrid-scale energy transfer in the wall layer. Presented at the 47th Annual Meeting of theAmerican Physical Society–Division of Fluid Dynamics, Atlanta, Georgia, November 1994.

20. Effects of mean flow three-dimensionality on the subgrid-scale stresses. Presented at the 48thAnnual Meeting of the American Physical Society–Division of Fluid Dynamics, Irvine, California,November 1995.

21. Effect of the subgrid-scale motions on Lighthill stress tensor. Presented at the 49th Annual Meetingof the American Physical Society–Division of Fluid Dynamics, Syracuse, New York, November1996.

22. Large-eddy simulation of laminar-turbulent transition in a swept-wing boundary layer. Presentedat the 35th Aerospace Sciences Meeting and Exhibit, Reno, Nevada, January 1997.

23. Scale-similar subgrid-scale stress models for large-eddy simulations. Presented at the 50th AnnualMeeting of the American Physical Society–Division of Fluid Dynamics, San Francisco, California,November 1997.

24. Large-eddy simulation of a three-dimensional shear-driven turbulent boundary layer. Presentedat the 3rd ERCOFTAC Workshop on Direct and Large-Eddy Simulation, Cambridge, UK, May1999.

25. A priori tests of SGS models in compressible turbulence. Presented at the 3rd ASME/JSME JointFluids Engineering Conference, San Francisco, California, July 1999.

26. Turbulence models in pulsating flows. Presented at the 39th Aerospace Sciences Meeting andExhibit, Reno, Nevada, January 2001.

27. Simulation of wake-induced transition on a flat plate. Presented at the 54th Annual Meeting of theAmerican Physical Society–Division of Fluid Dynamics, San Diego, California, November 2001.

28. Zonal approaches to wall-layer models for large-eddy simulations. Presented at the 3rd AIAATheoretical Fluids Meeting, St. Louis, MO, June 2002.

29. Interaction of the inner and outer layers in LES with wall models. Presented at the 5th Int. Symp.On Engineering Turbulence Modeling and Measurements, Mallorca, Spain, September 2002.

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30. On the use of hybrid RANS/LES methods for wall-layer modeling. Presented at the 55th AnnualMeeting of the American Physical Society–Division of Fluid Dynamics Dallas, Texas, November2002.

31. Large-eddy simulation of wall-bounded flows with a free surface. Presented at the 55th AnnualMeeting of the American Physical Society–Division of Fluid Dynamics Dallas, Texas, November2002.

32. Numerical simulations of wake/boundary-layer interactions. Presented at the 41st AerospaceSciences Meeting and Exhibit, Reno, Nevada, January 2003.

33. Synthetic Generation of Inflow Velocities for Large- Eddy Simulations. Presented at the AIAAFluid Dynamics Conference, Portland, Oregon, June 2004.

34. Large- Eddy Simulations of a Flow with Streamwise Curvature Changes. Presented at the AIAAFluid Dynamics Conference, Portland, Oregon, June 2004.

35. Synthetic inflow generation for LES of boundary-layer flows. Presented at the 57th Annual Meet-ing of the American Physical Society–Division of Fluid Dynamics, Seattle, Washington, Novem-ber 2004.

36. Interface conditions for hybrid RANS/LES calculations. Presented at the Conference on Engi-neering Turbulence Modeling and Experiments 6, Villasimius, Italy, May 2005.

37. Hybrid RANS/LES simulation of a flow with mild separation. Presented at the 61st Annual Meet-ing of the American Physical Society–Division of Fluid Dynamics, San Antonio, Texas, Novem-ber 2008.

38. Large eddy simulation of boundary layers with embedded spanwise vortices. Presented at the62nd Annual Meeting of the American Physical Society–Division of Fluid Dynamics, Minneapolis,Minnesota, November 2009.

39. A grid-independent length-scale for large-eddy simulations. Presented at the 62nd Annual Meetingof the American Physical Society–Division of Fluid Dynamics, Minneapolis, Minnesota, November2009.

40. A grid-independent length scale for large- eddy simulations of wall-bounded flows. Presented atthe 8th International ERCOFTAC Symposium on Engineering Turbulence Measurements andModelling, Marseilles, France, June 2010.

41. Numerical simulations of the flow over 3D river dunes. Presented at the 9th European FluidMechanics Conference, Rome, Italy, September 2012.

42. Numerical simulation of flow over three-dimensional dunes. Presented at the 65th Annual Meetingof the American Physical Society–Division of Fluid Dynamics, San Diego, California, November2012.

43. Large-eddy simulations of coherent vortices embedded in an impinging jet. Presented at the 65thAnnual Meeting of the American Physical Society–Division of Fluid Dynamics, San Diego, Cali-fornia, November 2012.

44. Coherent eddies in flows over three-dimensional dunes. Presented at the 66th Annual Meeting ofthe American Physical Society–Division of Fluid Dynamics, Pittsburgh, Pennsylvania, November2013.

45. A physics-based length-scale for large-eddy simulations. Presented at the Proc. 10th Int. Symp.Eng. Turbulence Modelling and Measurements - ETMM10, Marbella, Spain, August 2014.

46. Boundary layer separation under strong adverse pressure gradient over smooth and rough walls.Presented at the ERCOFTAC Symposium on Direct and Large-Eddy Simulations, DLES10, Li-massol, Cyprus, May 20, 2015.

47. Evaluation of turbulence models on roughened turbine blades. Presented at the 28th IAHR sym-posium on Hydraulic Machinery and Systems, Grenoble, France, July 4–8, 2016.

48. Application of integral length- scale approximation to wall- modeled LES. Presented at the 11thSymposium on Direct and Large-Eddy Simulations (DLES11), Pisa, Italy, May 2017.

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49. Rotating Channel Flows over Rough and Smooth Surfaces. Presented at the 70th Annual Meetingof the American Physical Society–Division of Fluid Dynamics, Denver (CO), November 2017.

50. Large-eddy and wall-modelled simulations of turbulent flow over two-dimensional river dunes.Presented at CFDSC18-Annual meeting of the CFD Society of Canada, Winnipeg, MB, June2018.

51. Effect of roughness on wall-bounded flows subjected to spanwise rotation. Presented at the 12thInt. ERCOFTAC Symp. Eng. Turbulence Modelling and Measurements, Montpellier, France, 26-28 September 2018.

I. Invited seminars

1. Evaluation of subgrid-scale turbulence models.

(a) Stanford University, Department of Mechanical Engineering, January 1986.

2. Computational research in the Heat Transfer and Turbulence Mechanics laboratories.

(a) Stanford University, Department of Mechanical Engineering, September 1986.

3. Models for large eddy simulation of turbulent channel flow.

(a) State University of New York at Buffalo, Department of Aerospace and Mechanical Engineer-ing, April 1987.

(b) University of Maryland–College Park, Department of Mechanical Engineering, May 1987.

4. Models for large eddy simulation of turbulent channel flow including transpiration.

(a) Stanford University, Department of Mechanical Engineering, November 1987.

5. Application of large eddy simulation to transitional, wall-bounded flows.

(a) University of Maryland-College Park, Department of Mechanical Engineering, May 1989.

6. Application of large eddy simulation to turbulent and transitional flows.

(a) Universita degli Studi di Roma, Dipartimento di Meccanica e Aeronautica, June 1989.

(b) Politecnico di Torino, Dipartimento di Ingegneria Aeronautica e Spaziale, June 1989.

7. Large-eddy simulation of transitional boundary layer and channel flows.

(a) Ohio State University, Department of Mechanical Engineering, March 1990.

(b) Brown University, Department of Applied Mathematics, April 1990.

(c) NASA Langley Research Center, June 1990.

8. Recent progress in large-eddy simulations.

(a) The Johns Hopkins University, Department of Mechanical Engineering, November 1990.

9. A dynamic subgrid-scale eddy viscosity model.

(a) Institute for Computer Applications in Science and Engineering, NASA Langley ResearchCenter, February 1990.

10. Large-eddy simulation of transitional flows.

(a) Politecnico di Torino, Dipartimento di Ingegneria Aeronautica e Spaziale, July 1991.

(b) Universita degli Studi di Roma “La Sapienza”, Dipartimento di Meccanica e Aeronautica,July 1991.

(c) David Taylor Research Center, September 1991.

11. The role of numerical simulations in the investigation of wall-layer structures.

(a) Universita degli Studi di Roma “La Sapienza”, Dipartimento di Meccanica e Aeronautica,July 1991.

12. Applications of the dynamic eddy viscosity model to the large-eddy simulation of transitional andturbulent flows.

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(a) Department of Mechanical and Aerospace Engineering – Program in Applied and Computa-tional Mathematics, Princeton University, November 1991.

13. Large-eddy simulation in the engineering sciences.

(a) Office of Naval Research, February 1992.

(b) McDonnell Douglas Research Laboratory, February 1992.

14. Recent applications of large-eddy simulation to transitional and turbulent flows.

(a) Naval Research Laboratory, June 1992.

15. Large-eddy simulation of transitional and turbulent flows.

(a) Universita degli Studi di Bologna, Dipartimento di Fisica Tecnica, January 1993.

(b) Universita degli Studi di Napoli “Federico II”, Istituto di Gasdinamica, January 1993.

16. Large-eddy simulation using the localized dynamic subgrid-scale eddy viscosity model.

(a) Minnesota Supercomputer Institute, University of Minnesota, October 1993.

(b) Sibley School of Mechanical and Aerospace Engineering, Cornell University, October 1993.

(c) Department of Mechanical Engineering, University of Vermont, October 1993.

(d) Department of Aerospace and Mechanical Engineering, University of Arizona, November 1993.

17. Dynamic subgrid-scale modeling of turbulent flows.

(a) Department of Mechanical and Aerospace Engineering, Illinois Institute of Technology, March1994.

(b) Department of Theoretical and Applied Mechanics, University of Illinois at Urbana-Champaign, March 1994.

(c) Department of Applied Mathematics, Brown University, May 1994.

(d) Department of Mechanical Engineering, University of Tokyo, July 1994.

(e) Department of Mechanical Engineering, Tokyo University of Technology, July 1994.

18. Subgrid-scale energy transfer in the wall layer.

(a) Department of Aerospace and Mechanical Engineering, University of Southern California,January 1995.

(b) Department of Applied Mathematics and Engineering Sciences, University of California atSan Diego, February 1995.

(c) IMHEF, Ecole Polytechnique Federale de Lausanne, May 1995.

(d) Institute of Fluid Dynamics, Swiss Federal Institute of Technology-Zurich , June 1995.

(e) Institute for Computer Applications in Science and Engineering, NASA Langley ResearchCenter, July 1995.

(f) The Johns Hopkins University, Department of Mechanical Engineering, November 1995.

19. Effect of the subgrid scales on the Lighthill stress tensor.

(a) George Washington University–JIAFS, July 1996.

20. Large-eddy simulations of non-equilibrium flows.

(a) University of Kentucky-Lexington, October 1996.

(b) Centre de Recherche en Calcul Applique (CERCA), Montreal, February 1997.

21. Introduction to large-eddy simulations.

(a) Department of Civil Engineering, Universita degli Studi di Trieste, Italy, June 1997.

22. Large-eddy simulation: present state and future directions.

(a) Department of Aerospace Engineering and Mechanics, University of Minnesota, March 1998.

(b) Department of Mechanical Engineering, University of Wisconsin, September 1998.

(c) Ecole Nationale Superieure d’Hydraulique et de Mecanique de Grenoble, Grenoble, France,January 1999.

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23. Applications of dynamic models to non-equilibrium flows.

(a) Ecole Nationale Superieure d’Hydraulique et de Mecanique de Grenoble, Grenoble, France,January 1999.

(b) Center for Environmental and Applied Fluid Mechanics, The Johns Hopkins University, Bal-timore, February 1999.

(c) The Levich Institute, The City University of New York, New York, February 1999.

24. Large-eddy simulations using wall-layer models

(a) Mechanical and Aerospace Engineering Department, Arizona State University, February 2001.

(b) NASA Langley Research Center, May 2001.

(c) The Boeing Company, August 2001.

(d) Department of Mechanical Engineering, Yale University, January 2002.

25. Numerical simulations of turbulent flows: when computers get the blues

(a) Department of Mechanical Engineering, University of Maryland, May 2001.

26. On the use of hybrid RANS/LES methods for wall-layer modeling.

(a) Department of Mechanical and Aerospace Engineering, Princeton University, February 2003.

(b) Department of Mechanical Engineering, Johns Hopkins University, March 2003.

(c) NSWCCD Hydro Colloquium, David Taylor Research Center, May 2003.

(d) Department of Mechanical and Aerospace Engineering, University of Virginia, January 2004.

27. Wall-layer models for large-eddy simulations of complex flows.

(a) Department of Mechanical Engineering, University of California, Riverside, May 2005.

(b) Woods Hole Oceanographic Institute, Woods Hole, August 2005.

28. Modern techniques for the simulation of turbulence.

(a) Department of Mechanical Engineering, Queen’s University, Kingston, Ontario, October 2005.

(b) Department of Mechanical Engineering, Politecnico di Bari, Bari (Italy), June 2006.

29. Turbulent eddies in the RANS/LES transition region.

(a) Department of Mechanical and Aerospace Engineering, University of California, San Diego(CA), September 2007.

(b) Department of Mechanical and Aerospace Engineering, Cornell University, Ithaca (NY),February 2009.

(c) Department of Mechanical and Industrial Engineering, University of Toronto, Toronto (On-tario), Canada, March 2009.

(d) Faculty of Applied Physics, TU Eindhoven, Eindhoven (The Netherlands), July 2009.

30. Large-eddy simulations of relaminarization due to freestream acceleration.

(a) Department of Mechanical Engineering, TU Delft, Delft (The Netherlands), June 2009.

31. Eddy-resolving simulations in aerodynamics: where R meets D.

(a) Department of Mechanical Engineering, Royal Military College of Canada, Kingston, Ontario,March 2010.

(b) Bombardier Aerospace, Advanced Aerodynamics Dept., Montreal (Quebec), March 2010.

(c) Dipartimento di Ingegneria delle Costruzioni, Ambiente e Territorio, Universita di Genova,Genova (Italy), June 2010.

(d) Department of Mechanical, Aerospace and Manufacturing Engineering, Syracuse University,Syracuse (NY), September 2010.

32. Numerical simulations of accelerating boundary layers over smooth and rough surfaces.

(a) University of Toronto Institute for Aerospace Sciences, Toronto (ON), March 2011.

(b) University of Maryland, College Park (MD), April 2011.

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(c) Department of Mechanical Engineering, University of Calgary, Calgary, (AB), May 2013.

(d) Department of Mechanical and Aerospace Engineering, City University, London (UK), Octo-ber 2013.

33. Eddy-resolving simulations: a tool in turbulence research.

(a) Department of Physics, Queen’s University, Kingston (ON), September 2012.

(b) Department of Mechanical and Industrial Engineering, Concordia University, Montreal (QC),February 2013.

(c) Department of Mechanical Engineering, University of Calgary, Calgary, (AB), May 2013.

34. Large-eddy simulations in dune dynamics research

(a) Saint Anthony’s Falls Laboratory, University of Minnesota, Minneapolis (MN), April 2014.

(b) Dipartimento di Fisica, Universita degli Studi di Roma “Tor Vergata”, September 2014.

35. Numerical simulations of rough-wall boundary layers

(a) Department of Aerospace Engineering, Iowa State University, Ames (IA), September 2015.

(b) Department of Mechanical Engineering, McGill University, Montreal (QC), January 2016.

(c) Department of Mechanical Engineering, University of Maryland, College Park (MD), April2016.

(d) Laboratoire de Dynamique des Fluides, Ecole Nationale Superieure d’Arts et Metiers, Paris(France), May 2016.

(e) University of Toronto Institute for Aerospace Studies, Toronto (ON), May 2016.

(f) Department of Mechanical Engineering, George Washington University, Washington (DC),April 2018.

(g) Center for Environmental and Applied Fluid Mechanics, Johns Hopkins University, Baltimore(MD), April 2019.

J. Conference proceedings

1. R. P. Garg and U. Piomelli “Large-eddy simulation of detuned transition in plane channel flow.”4th International Symposium on Computational Fluid Dynamics, Davis, California, September9–12, pp. 406–411, 1991.

2. P. Espina, U. Piomelli and G. E. Mattingly “A numerical investigation of the compressible flowfield produced by an annular jet, close-coupled, gas metal atomizer.” In Computational andNumerical Techniques in Powder Metallurgy, eds. D. Madan, I. Anderson, W. Frazier, P. Kumar,M. McKimpson, TMS, Warrendale PA, pp. 41–53, 1993.

K. Editorships, editorial boards and reviewing activities

1. Editor-in-Chief, Journal of Turbulence, Taylor and Francis (2015–Present).

2. Associate Editor, ASME Journal of Fluids Engineering (2003–2010).

3. Member of the Editorial Board, Journal of Turbulence, Taylor and Francis (2000-2015).

4. Guest Editor of the Special Issue on Large-eddy simulations of the International Journal of Com-putational Fluid Dynamics (Taylor and Francis), appeared in 2010.

5. With C. Cercignani, Guest Editor of the Special Issue on Turbulence modelling and simulationsof the journal Computer and Mathematics with Applications (Elsevier), appeared in 2003.

6. Article reviewer

(a) The Physics of Fluids.

(b) AiChE Symposium Series.

(c) International Journal for Numerical Methods in Fluids.

(d) International Journal of Heat and Fluid Flow.

(e) AIAA Aerospace Meetings.

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(f) AIAA Journal.

(g) ASME Journal of Fluids Engineering.

(h) Meccanica.

(i) Theoretical and Computational Fluid Dynamics.

(j) Journal of Fluid Mechanics.

(k) Computers and Fluids.

(l) Journal of Engineering Mathematics.

(m) Journal of Computational Physics.

(n) Physical Review E.

(o) Applied Scientific Research.

(p) Journal of Turbulence.

(q) Flow, Turbulence and Combustion.

(r) Fluid Dynamics Research.

(s) Proc. Inst. Mech. Engineers, Part G, J. Aerospace Engrng.

(t) J. Geophys. Res.

(u) Europ. J. Mech. B - Fluids

7. Proposal reviewer

(a) National Science Foundation.

(b) Swedish Research Council.

(c) HP2C (Platform for High-Performance and High-Productivity Computing, Switzerland).

(d) Consiglio Nazionale Ricerche (Italy).

(e) Ministero dell’Istruzione, dell’Universita e della Ricerca (Italy).

(f) National Sciences and Engineering Research Council (Canada).

CONTRACTS, GRANTS AND AWARDS

A. Grants (PI)

1. Development of subgrid-scale models for turbulent flows with heat transfer. University of Mary-land, College of Engineering, Minta Martin Fund. US$22,000. July 1988–June 1989.

2. Large eddy simulation of flows with embedded streamwise vortices. Office of Naval Research.US$113,080. December 1988–November 1990.

3. Application of large eddy simulation to transitional channel flow. National Aeronautics and SpaceAdministration. US$137,500. January 1990–December 1992.

4. Large eddy simulation of three-dimensional boundary layers. Office of Naval Research.US$230,268. February 1991–January 1994.

5. Large-eddy simulation of compressible and spatially-developing boundary layers. National Aero-nautics and Space Administration. US$105,415. January 1993–January 1996.

6. Large-eddy simulation of a three-dimensional, shear-driven boundary layer. Office of Naval Re-search. US$269,191. February 1994–January 1997.

7. Large-eddy simulation of the flow behind an array of vortex generators. The Boeing Company.US$36,111. September 1, 1994–August 31, 1995.

8. Large-eddy simulation of relaminarization and retransition. National Aeronautics and Space Ad-ministration. US$79,954. April 1996–March 1998.

9. Large-eddy simulation of the flow emission from unsteady flow separation. National Aeronauticsand Space Administration. US$156,402. December 1996–December 1999.

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10. Large-eddy simulation of attachment-line instability. National Aeronautics and Space Adminis-tration. US$55,555. December 1996–December 1997.

11. Large-eddy simulation of the flow over a low Reynolds-number airfoil. Air Force Office of ScientificResearch. US$185,430. April 1997–December 1998.

12. Wall-layer models for large-eddy simulations. Office of Naval Research. US$182,558. August1997–July 1999.

13. Large-eddy simulation of complex flows using wall-layer models. Office of Naval Research.US$198,438. August 1999–July 2001.

14. An LES/DNS Based Model for Wall-Pressure Fluctuations. NSWC-Carderock. US$65,108. July1999–June 2001.

15. Numerical investigation of the wave boundary layer. Woods Hole Oceanographic Institute.US$20,577. October 1999–September 2001.

16. Interaction between a laminar boundary layer and a far-field wake. National Aeronautics andSpace Administration, US$165,000. November 1999-October 2002.

17. Evaluation of MEMS ultrasonic transducer arrays for flow metering. National Institute of Stan-dards and Technology, US$191,316. May 2001-April 2004.

18. Comparison of Wall-Layer Modeling Techniques for large-eddy simulations. Office of Naval Re-search. US$146,424. August 2001–July 2003.

19. Inflow conditions for large-eddy simulations. Air Force Office of Scientific Research. US$253,203.January 2003–January 2006.

20. Transition mechanisms on multi-element airfoils. National Aeronautics and Space Administra-tion. US$209,342. April 2003–April 2006.

21. Wall-layer models for large-eddy simulations of complex flows. Office of Naval Research.US$173,238. April 2003–March 2005.

22. Collaborative Research: Large-eddy simulation of estuarine mixing. National Science Foundation.US$223,283. March 2005–February 2009.

23. Interface conditions for hybrid RANS/LES methods. Air Force Office of Scientific Research.US$286,156. January 2006–January 2009.

24. Local Grid Refinement in Large-Eddy Simulations. Office of Naval Research. US$173,621. March2006–September 2008.

25. Turbulence Simulations and Modelling. Queen’s University Research Initiation Grant,Can$62,500. August 2008.

26. Computational Turbulence Research. CRC-CFI, ORF and Queen’s University. Can$333,333.

27. Large-eddy simulations of complex flows. Natural Sciences and Engineering Research Council(NSERC) of Canada Discovery Grant. Can$285,000. October 2009–October 2014.

28. Large-eddy simulations of jets with embedded vortices impinging on a flat surface. Air Force Officeof Scientific Research, US$304,687. September 2010–August 2014.

29. Numerical simulation of turbulence in hydro-electric applications. Natural Sciences and Engineer-ing Research Council (NSERC) of Canada Collaborative Research and Development Grant (withHydro Quebec), Can$431,400. January 2012–December 2015.

30. Large-eddy simulations of complex flows. Natural Sciences and Engineering Research Council(NSERC) of Canada Discovery Grant. Can$290,000. June 2016–May 2021.

31. Numerical simulation and modelling of non-equilibrium flows in hydro-power applications. Natu-ral Sciences and Engineering Research Council (NSERC) of Canada Collaborative Research andDevelopment Grant (with Hydro Quebec), Can$369,520. December 2017–November 2022.

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B. Grants (Co-PI)

1. Studies of the vortical structure of the turbulent boundary layer and its control. National ScienceFoundation. US$388,015, with J. M. Wallace and J.-L. Balint. Responsible for approximatelyUS$130,000. October 1989–September 1992.

2. Vortical structures in turbulent shear flows and their implications for subgrid scale modeling.National Science Foundation. US$390,000, with J. M. Wallace. Responsible for approximatelyUS$130,000. July 1993–June 1996.

3. Experimental study of a 3D, shear-driven boundary layer. National Aeronautics and Space Ad-ministration. US$25,000, with J. M. Wallace. July 1993–June 1994. Responsible for approxi-mately US$12,500.

4. Experimental and numerical studies of vorticity dynamics and passive scalar mixing in a turbu-lent mixing layer. National Science Foundation. US$350,000, with J. M. Wallace and L. Ong. Re-sponsible for approximately US$100,000. June 1997–May 2000.

5. Numerical modeling of non-premixed flame-wall interactions. National Science Foundation.US$239,541, with A. Trouve. March 2006–March 2009.

6. COX-2 Pathway and Cardiovascular Disease. Canadian Institutes for Health Research.Can$871,090, with Colin D. Funk.

7. Natural Laminar Flow Nacelle Lip in Composite. Consortium for Aerospace Research in Canada.Can$3,684,245. PI Reza Sadri (Bombardier Aerospace). Responsible for Can$315,482. April2017-March 2020.

C. Fellowships and awards

1. Fellow, Royal Society of Canada, 2015.

2. Fellow, American Physical Society, 2002.

3. Fellow, American Society of Mechanical Engineers, 2009.

4. Elected fellow, Institute of Physics, 2004.

5. Associate Fellow, American Institute of Aeronautics and Astronautics, 2004.

6. Tier I Canada Research Chair in Computational Turbulence, 2008.

7. Tier I Canada Research Chair in Turbulence Simulation and Modelling, 2015.

8. HPCVL-Sun Microsystems Chair in Computational Science and Engineering, 2008.

9. Aeritalia Scholarship for Academic Achievement, 1979.

10. Fulbright Travel Grant, 1981.

11. NASA Langley Research Center Award for Group Accomplishment - Hypersonic Boundary-Layer,1989.

12. NASA Langley Research Center Award for Group Accomplishment - Flow Prediction and Control,1994.

TEACHING AND ADVISING

A. Undergraduate courses taught

1. At the University of Maryland

(A) Statics (ENES102). Spring 1996.

(B) Dynamics (ENES221). Spring 1988, Fall 1988, Spring 1991, Fall 1991, Fall 1995, Spring 2003.

(C) Thermodynamics (ENME232). Fall 2006.

(D) Thermodynamics (ENME320). Spring 1999, Fall 1999, Spring 2006.

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(E) Fluid mechanics (ENME342). Spring 1988, Fall 1988, Spring 1993.

(F) Fluid mechanics (ENME331). Spring 2001, Fall 2003, Spring 2005, Spring 2007, Spring 2008.The ENME342 curriculum was changed to include a studio section, and the new course wasrenumbered ENME331.

2. At Queen’s University

(A) Fluid mechanics I (MECH241). Winter 2010.

(B) Airplane aerodynamics and performance (MECH480). Formerly Introduction to AerospaceEngineering. Winter 2011, Winter 2013, Winter 2014, Winter 2015, Winter 2016, Winter2017, Winter 2018, Winter 2019.

B. Graduate courses taught

1. At the University of Maryland

(A) Fundamentals of Fluid Mechanics (ENME640). Fall 1992, Fall 1993, Fall 1997, Fall 1998, Fall2000, Fall 2001, Fall 2002.

(B) Computational Fluid Dynamics (ENME646, earlier ENME808A). Spring 1989, Spring 1990,Spring 1992, Fall 1994, Fall 1996, Spring 1998, Spring 2000, Spring 2002, Spring 2004, Fall2005, Fall 2007. New course developed by UP.

(C) Physics of Turbulence (ENME656). Spring 1997.

(D) Advanced Mechanical Engineering Analysis I (ENME700) Fall 1989, Fall 1990.

(E) Turbulence Simulations (ENME808Q). Fall 2004, Spring 2006. New course developed by UP.

2. At Queen’s University

(A) Advanced Topics in Numerical Modelling of Fluid Flow (MECH934). Fall 2010, Fall 2013.

(B) Turbulence Simulations (MECH935). Fall 2009, Fall 2012, Fall 2014.

(C) Introduction to Computational Fluid Dynamics (MECH835). Fall 2015 (New course developedby UP), Fall 2017.

(D) Introduction to turbulence (MECH839). Fall 2016 (New course developed by UP), Fall 2018.

C. Advising

1. M. S. students advised at the University of Maryland

(A) Rajat Garg, Fall 1991. Present employment: Sun Microsystems. Thesis.

(B) Yunfang Yu, Fall 1994. Non-Thesis.

(C) Biren Mowli, Fall 1998. Present employment: Amazon. Thesis.

(D) Chandrasekhar Kannepalli, Fall 1997. Present employment: Combustion Research And FlowTechnology, Inc. Non-Thesis.

2. M. A. Sc. students advised at Queen’s University

(A) Junlin Yuan, Fall 2011. Present employment: Present employment: Assistant Professor,Michigan State University (East Lansing, MI, USA).

(B) Amireza Rouhi, Winter 2012. Present employment: Ph.D. student, Queen’s University.

(C) Pouya Mottaghian, Spring 2016.

(D) Mojtaba Mellati Nokhandan, Fall 2017 (expected).

3. Ph. D. students advised at the University of Maryland

(A) Hossein Esmaili, Spring 1992. Present employment: U.S. Nuclear Regulatory Commission,Rockville, MD, USA.

(B) Junhui Liu, Fall 1994. Present employment: Naval Research Laboratory, Washington, DC,USA.

(C) Xiaoli Huai, Summer 1996. Present employment: Ford Motors.

(D) Pedro I. Espina, Fall 1997. Present employment: National Insititue of Standards andTechnoglogy (NIST), Gaithersburg, MD (USA).

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(E) Peter A. Chang, III, Summer 1998. Present employment: Naval Surface WeaponsLaboratory–Carderock Division, Bethesda, MD, USA.

(F) Chandrasekhar Kannepalli, Spring 1999. Present employment: Combustion Research AndFlow Technology, Inc.

(G) G. Valter Diurno, Spring 2001. Present employment: CD Adapco.

(H) Victor Ovchinnikov, Spring 2006. Present employment: Postdoctoral Fellow, Harvard Uni-versity.

(I) Giuseppe De Prisco, Spring 2007. Present employment: Statoil, Houston, TX, USA.

(J) Senthil Radhakrishnan, Fall 2007. Present employment: Postdoctoral Fellow, University ofCalifornia, Santa Barbara.

4. Ph. D. students advised at Queen’s University

(A) Carlo Scalo, Summer 2012. Present employment: Assistant Professor, Purdue University(West Lafayette, IN, USA).

(B) Mohammed Omidyeganeh, Spring 2013. Present employment: Assistant Professor, City Uni-versity, (London, UK).

(C) Junlin Yuan, Summer 2015. Present employment: Assistant Professor, Michigan State Uni-versity (East Lansing, MI, USA).

(D) Rayhaneh Banyassady, Summer 2015.

(E) J. S. Aidin (Civil Engineering, co-supervised with L. Boegman), Fall 2015.

(F) Wen Wu, Winter 2016. Present employment: Postdoctoral Fellow, Johns Hopkins University.

(G) Amirreza Rouhi, Fall 2016. Present employment: Postdoctoral Fellow, University of Mel-bourne.

(H) Vishal Kumar, Fall 2020 (expected).

(I) Gianmarco d’Alessandro, Fall 2021 (expected).

(J) Zvi Hantsis, Fall 2021 (expected).

(K) Ming Teng, Fall 2022 (expected).

5. Post-Doctoral Associates supervised at the University of Maryland.

(A) Junhui Liu, 1994–1995. Present employment: Naval Research Laboratory.

(B) Fabrizio Sarghini, 1996–1998. Present employment: Assistant Professor, Department of Agri-cultural Engineering, University of Naples, Italy.

(C) Andrea Pascarelli, 1997–2000. Present employment: Department of Foreign Affairs, Rome,Italy.

(D) Elias Balaras, 1998–2000. Present employment: Professor, Department of Mechanical andAerospace Engineering, George Washington University.

(E) Pamela Moore, 2001–2004.

(F) Alexandre Silva Lopes. 2001–2004. Present employment: Faculty of Engineering, Universityof Porto, Porto, Portugal.

(G) Anthony Keating. 2003–2005. Present employment: University of Queensland.

(H) Senthil Radhakrishnan, 2007–2008. Present employment: University of California, SantaBarbara.

6. Post-Doctoral Fellows supervised at Queen’s University.

(A) Matthew Ford, 2009–2011. Present employment: Royal Bank of Canada.

(B) Iftekhar Z. Naqavi, 2008–2010. Present employment: University of Cambridge (UK).

(C) Valerio Grazioso, 2009–2010. Present Employment: University of Naples (Italy).

(D) Hassan Raiesi, 2011. Present employment: Bombardier Aerospace.

(E) Mohammed Omidyeganeh, Summer 2013. Present employment: Assistant Professor, CityUniversity, London (UK).

(F) Rabijhit Dutta, 2014–2016. Present employment: Postdoctoral Fellow, University of Idaho.

(G) Wen Wu, 2016–2017. Present employment: Postdoctoral Fellow,Johns Hopkins University.

(H) Ankhit Awasthi, 2018–Present.

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SERVICE

A. Professional

1. Conference Chairman or Organizer

(A) Co-Organizer, Symposium on Engineering Applications of Large-Eddy Simulations, 1993ASME Fluids Engineering Conference, Washington, D.C., June 20-23, 1993.

(B) Member of the Scientific Committee, First AFOSR International Conference on DNS andLES, Louisiana Tech. University, August 4–8, 1997.

(C) Member of the Scientific Committee, Second AFOSR International Conference on DNS andLES, Rutgers University, August 1999.

(D) Member of the Advisory Committee, 1st Symp. on Turbulent Shear Flow Phenomena, SantaBarbara, September 1999.

(E) Member of the Organizing Committee, 53rd Annual Meeting of the American Physi-cal Society–Division of Fluid Dynamics, Washington, November 2000.

(F) Member of the Scientific Committee, Third AFOSR International Conference on DNS andLES, University of Texas-Arlington, August 2001.

(G) Member of the Advisory Committee, 2nd International Symp. on Turbulent Shear Flow Phe-nomena, Stockholm, Sweden, September 2001.

(H) Member of the Advisory Committee, 3rd International Symp. on Turbulent Shear Flow Phe-nomena, Sendai, Japan, June 2003.

(I) Member of the Organising Committee, 4th International Symp. on Turbulent Shear FlowPhenomena, Williamsburg, June 2005.

(J) Co-director, von Karman Institute 2005–2006 Lecture Series on “Large Eddy Simulation AndRelated Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, March 2006.

(K) Assistant Organizer, AIAA Summer Meeting, Miami, June 2007.

(L) Assistant Organizer, AIAA Aerospace Sciences Meeting, Reno, Nevada, January 2008.

(M) Co-director, von Karman Institute 2007–2008 Lecture Series on “Large Eddy Simulation AndRelated Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, March 2008.

(N) Member of the Advisory Committee, 7th International ERCOFTAC Symposium on Engi-neering Turbulence Modelling and Measurements, Limassol, Cyprus, June 2008.

(O) Co-director, von Karman Institute 2009–2010 Lecture Series on “Large Eddy SimulationAnd Related Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, Febru-ary 2010.

(P) Member of the Advisory Committee, 8th International ERCOFTAC Symposium on Engi-neering Turbulence Modelling and Measurements, Marseilles, France, June 2010.

(Q) Member of the Organising Committee, 7th Symposium on Turbulent Shear Flow Phenomena,Ottawa, June 2011.

(R) Co-director, von Karman Institute 2011–2012 Lecture Series on “Large Eddy SimulationAnd Related Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, Febru-ary 2012.

(S) Member of the Scientific Committee, ERCOFTAC Workshop on Direct and Large-Eddy Sim-ulation 9, Dresden, Germany, April 2013.

(T) Member of the Scientific Advisory Committee, 10th International ERCOFTAC Symposiumon. Engineering Turbulence Modelling and Measurements, Marbella, Spain, September 2014.

(U) Co-director, von Karman Institute 2013–2014 Lecture Series on “Large Eddy SimulationAnd Related Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, Febru-ary 2014.

(V) Member of the Scientific Committee, ERCOFTAC Workshop on Direct and Large-Eddy Sim-ulation 10, Limassol, Cyprus, May 2015.

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(W) Co-director, von Karman Institute 2015–2016 Lecture Series on “Large Eddy Simulation AndRelated Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, May 2016.

(X) Member of the Scientific Advisory Committee, 11th International ERCOFTAC Symposiumon. Engineering Turbulence Modelling and Measurements, Palermo, Italy, September 2016.

(Y) Member of the Scientific Committee, ERCOFTAC Workshop on Direct and Large-Eddy Sim-ulation 11, Pisa, Italy, May 2017.

(Z) Co-director, von Karman Institute 2015–2016 Lecture Series on “Large Eddy Simulation AndRelated Techniques: Theory And Applications”, Rhode-Saint-Genese, Belgium, May 2018.

(AA) Member of the Scientific Advisory Committee, 12th International ERCOFTAC Symposiumon. Engineering Turbulence Modelling and Measurements, Montpellier, France, September2016.

B. University (at the University of Maryland)

1. Departmental

(A) Organizer of the Fluid Dynamics Review Seminars. 1988–1990 and 1993.

(B) Department of Mechanical Engineering representative, United Charity Campaign. 1989–1991.

(C) Thermal/Fluids Sciences Committee for Graduate Recruitment. Fall 1989–Fall 1993.

(D) Department of Mechanical Engineering Graduate Committee. Fall 1989–Spring 1998.

(E) Department of Mechanical Engineering Graduate Curriculum Committee. Fall 1993.

(F) Search committee for Thermal/Fluid faculty. Fall 1993, Fall 1997.

(G) Acting Director of Graduate Studies. Fall 1996–Summer 1997.

(H) Search committee for the Computer network specialist. Fall 1996.

(I) Department of Mechanical Engineering Graduate Curriculum Committee. Fall 1997.

(J) Department of Mechanical Engineering Faculty Salary Committee. Fall 1997–Spring 2002.

(K) Department of Mechanical Engineering Faculty Advisory Committee. Spring 2002–June 2006.

(L) Department of Mechanical Engineering Operating Committee. Spring 2002–June 2006.

(M) Chair of the Department of Mechanical Engineering Appointments, Promotion and TenureCommittee. Fall 2001–Summer 2004.

(N) Chair of the Department of Mechanical Engineering Graduate Committee. Fall 2001–June2006.

(O) Chair of the Search Committee for the Graduate Coordinator. Fall 2001, Summer 2002.

(P) Search Committee for the Assistant Director, Human Resources. Summer 2005.

2. College

(A) Search committee for the Operations Coordinator – Instructional Television Service. Summer1989.

(B) College Web Committee. Spring 1997.

(C) College Appointment, Promotion and Tenure Committee. Fall 1996-Spring 1998.

(D) Search committee for the Mechanical Engineering Chair. Fall 2000–Spring 2001.

(E) College Graduate Directors’ Committee. Summer 2001–Summer 2006.

(F) Ph.D. Retention Committee, Spring 2005–Spring 2006.

(G) Appointment, Promotion and Tenure Committee, A.J. Clark School of Engineering. Summer2007–June 2005.

3. University

(A) Campus Senate. Fall 1990–Spring 1993.

(B) Graduate Council. Fall 2007–Summer 2008.

C. University (at Queen’s University)

1. Department

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(A) Appointments, Promotion and Tenure Committee, 2013–2014.

(B) Graduate Committee, 2015–present.

(C) Leader, Energy and Fluids Systems Division, 2016–present.

(D) Curriculum Committee, 2017–present.

(E) Math and analysis course revision committee, 2018–present.

2. Faculty

(A) Faculty Awards Committee.

3. University

(A) Research Strategic Planning Committee, 2011–2014.

(B) Water Research Centre Executive Committee, 2012–present.

(C) Data, Analytics and Computing Committee, 2014–2015.

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Ugo Piomelli - me.queensu.ca · 7.U. Piomelli, P. Moin, and J. H. Ferziger \Large eddy simulation...

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