Donald McEligot, Ph.D.

Visiting Professor

Phone

208-533-8120

DonaldM@uidaho.edu

Mailing Address

University of Idaho — CAES MS 3560
995 MK Simpson Boulevard
Idaho Falls, ID 83401

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College of Engineering

Nuclear Engineering

Ph.D., Thermoscience, Stanford University
M.S.E., Nuclear Engineering, University of Washington
B.E.M.E., Mechanical Engineering, Yale University

Research/Focus Areas

Fluid dynamics
- Complex turbulent and transitional shear flow
- Entropy generation
Convective heat transfer
Experimental, analytical and computational approaches (thermal hydraulics)

Donals McEligot — a thermal scientist at the Center for Advanced Energy Studies in Idaho Falls — is a visiting professor in the Nuclear Engineering Division at the University of Idaho, a professor emeritus of University of Arizona and a Nuclear Science (Directorate) Fellow at the Idaho National Laboratory. He has over three decades experience in development, use and guidance of experimental thermal science and computational thermal fluid physics. He is known for his pioneering experiments and numerical analyses on transport property variation in internal turbulent, laminar and laminarizing gas flows and discovery of laminarization by heating. He was the first to identify and predict properly low-Reynolds-number turbulent flow in tubes, to measure transition of mixtures of polymer solutions and to measure effects of heat transfer to low Prandtl number gas mixtures. He has been honored by receipt of the 2007 ASME Heat Transfer Memorial Award, their Heat Transfer Division 75^th Anniversary Medal and the 2011 iNEER Leadership Award, an award as a Senior Fulbright Research Scholar to West Germany, selection to ASME Fellow, receipt of the Charles H. Jennings Memorial Award from the American Welding Society, naming as the 2002 Distinguished Scientist by the Idaho Academy of Science and 1996 JAERI Distinguished Foreign Scientist and promotion to Captain, USNR. The author of more than sixty archival publications, he has completed research projects at Imperial College of Science and Technology/London, Universität Karlsruhe, the Max Planck Institut für Strömungsforschung/Göttingen, Universität Stuttgart, Universität der Bundewehr München and U. Limerick. His recent studies include laminar-to-turbulent transition in duct entry regions, dissipation and entropy generation in turbulent, transitional and laminar flows, thermal fluid dynamics of prismatic gas-cooled reactors and heat transfer to supercritical-pressure fluids.

Research Projects

Laminar-to-turbulent transition in duct entry regions
Dissipation and entropy generation in turbulent, transitional and laminar flows
Thermal fluid dynamics of prismatic gas-cooled reactors
Heat transfer to supercritical-pressure fluids

Funded Research

Air Force Office of Scientific Research
Army Research Office - Durham
Bechtel Corporate Funded R&D program
Bundesministierium für Forschung und Technologie
Department of Energy
- Basic Energy Sciences EPSCoR program
- Environmental Management Science program
- Gas-cooled Fast Reactor program
- International Nuclear Energy Research Initiative - Korea and France
- Nuclear Energy Research Initiative
- Savannah River Reactor Re-start program
- Supercritical Water Reactor program
- Very High Temperature Reactor program
- Nuclear Energy University Program
INEEL
- Faculty/staff Exchange program
- Long Term Research Initiative
- Laboratory-Directed Research and Development program
Max Planck Gesellschaft
National Science Foundation
Nuclear Regulatory Commission
Office of Naval Research
- Applied Hydrodynamics program
- Heat Transfer program
- Materials Science program
U. S. Naval Underwater Systems Center
U. S.-Deutschland Fulbright Commission
University of Arizona
Westinghouse Independent Research and Development Program

Awards and Honors

ASME Heat Transfer Memorial Award, 2007
iNEER Leadership Award from International Network of Engineering Education and Research (iNEER), 2011
75^th Anniversary Medal of the ASME Heat Transfer Division, 2013
Charles H. Jennings Memorial Award, American Welding Society, 1992
Distinguished Foreign Scientist, Japan Atomic Energy Research Institute, 1996
Senior Fulbright Research Scholar to West Germany, 1982-3
Distinguished Visiting Professor, Institut für Kernenergetik und Energiesysteme (IKE), Universität Stuttgart; 2005-8
2002 Distinguished Scientist by the Idaho Academy of Science
Lockheed Martin Corporation NOVA Award, 1998

Professional Activities

Fellow, American Society of Mechanical Engineers (ASME)
Member, American Nuclear Society (ANS)
Member, American Physical Society (APS)
Member, American Society for Engineering Education (ASEE)
Member, International Network for Engineering Education and Research (iNEER)
Associate Technical Editor, ASME Journal of Heat Transfer, 1986-1992
U. S. Scientific Committee, 12^th International Heat Transfer Conference, 2002
ASME Heat Transfer Division

Gas Turbine Committee (K-14), 1974-present
General Papers Committee, 1980-82; Chairman - 1981-1982

ASME Gas Turbine Division, Heat Transfer Committee, 1974-present
International Advisory Committee, 3^rd International Meeting of Specialists on Heat Transfer and Fluid Dynamics at Supercritical Pressure (HFSCP2016), University of Sheffield, 2016
IAEA (International Atomic Energy Agency) Advisory Committee for Coordinated Research Programme (CRP) on Heat Transfer Behaviour and Thermohydraulics Code Testing for Supercritical Water-cooled Reactors, 2006-8
ANS Aerospace Nuclear Science and Technology Technical Group, Executive Committee, 2000-2005

Selected Publications

Swank, W. D., F. I. Valentin, M. Kawaji and D. M. McEligot, 2017. Thermal conductivity of G-348 isostatic graphite. Nuclear Technology, in press.
McEligot, D. M., and R. W. Johnson, 2017. Bypass flow resistance in prismatic gas-cooled nuclear reactors. J. Nuc. Eng. and Radiation Sci., 3, No. 1, pp. 011003-1 to 9. Available via asmedigitalcollection.asme.org/nuclearengineering.
Valentin, F. I., N. Artoun, R. Anderson, M. Kawaji and D. M. McEligot, 2016. Study of convection heat transfer in a very high temperature reactor flow channel: Numerical and experimental results. Nuclear Technology, 196, pp. 661-673. Available as http://dx.doi.org/10.13182/NT16-46 or www.ans.org/pubs/journals/nt/a_39600.
Ricco, P., E. J. Walsh, F. Brighenti and D. M. McEligot, 2016. Growth of boundary-layer streaks due to free-stream turbulence. Int. J. Heat Fluid Flow, 61, pp. 272-283. Available as http://dx.doi.org/10.1016/j.ijheatfluidflow.2016.05.003.
Chu, X., E. Laurien and D. M. McEligot, 2016. Direct numerical simulation of strongly heated air flow in a vertical pipe. Int. J. Heat Mass Transfer, 101, pp. 1163-1176..
Ghasemi, E., D. M. McEligot, K. P. Nolan, J. Crepeau, A. Siahpush, R. S. Budwig and A. T. Tokuhiro, 2014. Effects of adverse and favorable pressure gradients on entropy generation in a transitional boundary layer region under the influence of freestream turbulence. Int. J. Heat Mass Transfer, 77, pp. 475-488.
George, J., L. D. Owen, T. Xing, D. M. McEligot, J. C. Crepeau, R. S. Budwig and K. P. Nolan, 2014. Entropy generation in bypass transitional flows. J. Hydrodynamics, 26, pp. 669-680.
McEligot, D. M., and E. J. Walsh, 2014. Entropy generation in steady laminar boundary layers with pressure gradients. Entropy, 16, pp. 3808-3813.
Ghasemi, E., D. M. McEligot,, K. P. Nolan, J. C. Crepeau, A. Tokuhiro and R. S. Budwig, 2013. Entropy generation in a transitional boundary layer region under the influence of freestream turbulence using transitional RANS models and DNS. Int. Comm. Heat Mass Transfer. 41, pp. 10-16.
Rehill, B., E. J. Walsh, P. Schlatter, L. Brandt, T. Zaki and D. M. McEligot, 2013. Identifying turbulent spots in transitional boundary layers. J. Turbomachinery, 146, pp. 011019-1 to -8.
Becker, S., D. M. McEligot, E. J. Walsh and E. Laurien, 2012. Entropy generation in a flow transitioning downstream of a rib. Turbulence, Heat and Mass Transfer 7 (Ed.: K. Hanjalic, Y. Nagano, D. Borello and S. Jakirlic), New York: Begell House.
Walsh, E. J., D. M. McEligot, L. Brandt and P. Schlatter, 2011. Entropy generation in boundary layers transitioning under the influence of freestream turbulence. J. Fluids Engr., 133, pp. 061203-1 to -10.
Nolan, K. P., E. J. Walsh and D. M. McEligot, 2010. Quadrant analysis of a transitional boundary layer subject to freestream turbulence. J. Fluid Mech., 658, pp. 310-335.
McIlroy, H. M, D. M. McEligot and R. J. Pink, 2010. Measurement of turbulent flow phenomena for the lower plenum of a prismatic gas-cooled reactor. Nuc. Engr. Design, 240. pp. 416-428.
Rehill, B., E. J. Walsh, K. Nolan, D. M. McEligot, L. Brandt, P. Schlatter and D. S. Henningson, 2010. Entropy generation rate in turbulent spots in a boundary layer subject to freestream turbulence. Seventh IUTAM Symposium on Laminar-Turbulent Transition (Ed.: P. Schlatter and D. S. Henningson), Dordrecht: Springer, pp. 557-560.
McEligot, D. M., R. S. Brodkey and H. Eckelmann, 2009. Laterally converging duct flows: Part 4. Temporal behavior in the viscous layer. J. Fluid Mech., 634, pp. 433-461.
Bae, J. H., J. Y. Yoo, H. Choi and D. M. McEligot, 2008. Structure of turbulent boundary layers developing in a heated vertical annular pipe at supercritical pressure. Phys. Fluids, 20, pp. 055108-1 to - 20 . Available online as doi:10.1063/1.2927488.
McEligot, D. M., E. J. Walsh, E. Laurien and P. R. Spalart, 2008. Entropy generation in the viscous parts of a turbulent boundary layer. J. Fluids Engr., 130, pp. 061205-1 to -12.
McEligot, D. M., K. P. Nolan, E. J. Walsh and E. Laurien, 2008. Effect of pressure gradients on entropy generation in the viscous layers of turbulent wall flows. Int. J. Heat Mass Transfer, 51, pp. 1104-1114.
Lee, J. I., P. Hejzlar, P. Saha, M. S. Kazimi and D. M. McEligot, 2008. Deteriorated turbulent heat transfer (DTHT) of gas up-flow in a circular tube: Experimental data. Int. J. Heat Mass Transfer, 51, pp. 3259-3266.
Lee, J. I., P. Hejzlar, P. Saha, M. S. Kazimi and D. M. McEligot, 2008. Deteriorated turbulent heat transfer of gas up-flow in a circular tube: Heat transfer correlations. Int. J. Heat Mass Transfer, 51, pp. 5318-5326.
Hernon, D., E. J. Walsh and D. M. McEligot, 2007. Experimental investigation into the route to bypass transition and the shear sheltering phenomenon. J. Fluid Mech., 591, pp. 461-479.
Walsh, E. J., K. P. Nolan, D. M. McEligot, R. J. Volino and A. Bejan, 2007. Conditionally-sampled turbulent and non-turbulent measurements of entropy generation rate in the transition region of boundary layers. J. Fluids Eng., 129, pp. 659-664.
Bae, J. H., J. Y. Yoo, H. Choi and D. M. McEligot, 2006. Effects of large density variation in strongly-heated internal air flows. Phys. Fluids, 18, pp. 075102-1 to -25.
McEligot, D. M., and H. Eckelmann, 2006. Laterally converging duct flows: Part 3. Mean turbulence structure in the viscous layer. J. Fluid Mech., 549, pp. 25-59.
McEligot, D. M., and J. D. Jackson, 2004. "Deterioration" criteria for convective heat transfer in gas flow through non-circular ducts. Nuc. Engr. Design, 232, pp. 327-333.
Xu, X., J. S. Lee, R. H. Pletcher, A. M. Shehata and D. M. McEligot, 2004. Large eddy simulation of turbulent forced gas flows in vertical pipes with high heat transfer rates. Int. J. Heat Mass Transfer, 47, pp. 4113-4123.
Mikielewicz, D. P., A. M. Shehata, J. D. Jackson and D. M. McEligot, 2002. Temperature, velocity and mean turbulence structure in strongly-heated internal gas flows. Comparison of numerical predictions with data. Int. J. Heat Mass Transfer, 45, pp. 4333-4352.
Becker, S., C. M. Stoots, K. G. Condie, F. Durst and D. M. McEligot, 2002. LDA-measurements of transitional flows induced by a square rib. J. Fluids Engr., 124, pp. 108-117.
McCreery, G. E., K. G. Condie, R. L. Clarksean and D. M. McEligot, 2002. Convective processes in spent nuclear fuel canisters. Heat Transfer 2002 (Twelfth International Heat Transfer Conference, Grenoble, August), Vol. 4, pp. 663-668.
Satake, S.-i., T. Kunugi, A. M. Shehata and D. M. McEligot, 2000. Direct numerical simulation of laminarization of turbulent forced gas flows in circular tubes with strong heating. Int. J. Heat Fluid Flow, 21, pp. 526-534.
Nishimura, M., S. Fujii, A. M. Shehata, T. Kunugi and D. M. McEligot, 2000. Prediction of forced gas flows in circular tubes at high heat fluxes. J. Nuc. Sci. Tech. (Atomic Energy Society of Japan), 37, pp. 581-594.
Ezato, K., A. M. Shehata, T. Kunugi and D. M. McEligot, 1999. Numerical predictions of transitional features of turbulent gas flows in circular tubes with strong heating. J. Heat Transfer, 121, pp. 546-555.
Shehata, A. M., and D. M. McEligot, 1998. Mean turbulence structure in the viscous layer of strongly-heated internal gas flows. Measurements. Int. J. Heat Mass Transfer, 41, pp. 4297-4313.
McEligot, D. M., J. E. O'Brien, C. M. Stoots, T. K. Larson, W. A. Christenson, D. C. Mecham and W. G. Lussie, 1994. Natural convection between a vertical cylinder and a surrounding array. Nuc. Engr. Design, 146, pp. 267-276.
Kim, Y.-S., D. M. McEligot and T. W. Eagar, 1991. Approximate analyses of electrode heat transfer in Gas Metal Arc Welding. Welding Journal, 70, pp. 20s-31s.
Taylor, M. F., K. E. Bauer and D. M. McEligot, 1988. Internal convective heat transfer to gas mixtures. Int. J. Heat Mass Transfer, 31, pp. 13-25.
McEligot, D. M., 1985. Measurement of wall shear stress in favorable pressure gradients. Lec. Notes Physics, 235, pp. 292-303.
Berner, C., F. Durst and D. M. McEligot, 1984. Flow around baffles. J. Heat Transfer, 106, pp. 743-749.
Murphy, H. D., F. W. Chambers and D. M. McEligot, 1983. Laterally converging flow. I: Mean flow. J. Fluid Mech., 127, pp. 379-401.
Chambers, F. W., H. D. Murphy and D. M. McEligot, 1983. Laterally converging flow. II: Temporal wall shear stress. J. Fluid Mech., 127, pp. 403-428.
Park, J. S., M. F. Taylor and D. M. McEligot, 1982. Heat transfer to pulsating turbulent gas flow. Heat Transfer 1982 (7th Intl. Heat Transfer Conf., München), Vol. 3, pp. 105-110.
Pickett, P. E., M. F. Taylor and D. M. McEligot, 1979. Heated turbulent flow of helium-argon mixtures in tubes. Int. J. Heat Mass Transfer, 22, pp. 705-719.
Serksnis, A. W., M. F. Taylor and D. M. McEligot, 1978. Turbulent flow of hydrogen-carbon dioxide mixtures in heated tubes. Heat Transfer 1978 (Sixth Int. Heat Transfer Conf., Toronto), Vol. 2, pp. 163-168.
McEligot, D. M., M. F. Taylor and F. Durst, 1977. Internal forced convection to mixtures of inert gases. Int. J. Heat Mass Transfer, 20, pp. 475-486.
Perkins, K. R., and D. M. McEligot, 1975. Mean temperature profiles in heated laminarizing air flows. J. Heat Transfer, 97, pp. 589-593.
Bates, J. A., R. A. Schmall, G. A. Hasen and D. M. McEligot, 1974. Effects of buoyant body forces on forced convection in heated laminarizing flows. Heat Transfer 1974 (Fifth Int. Heat Transfer Conf., Tokyo), Vol. II, pp. 141-145.
Bradshaw, P., R. B. Dean and D. M. McEligot, 1973. Calculations of interacting turbulent shear layers: Duct flow. J. Fluids Eng., 95, pp. 214-220.
Perkins, K. R., K. W. Schade and D. M. McEligot, 1973. Heated laminarizing gas flow in a square duct. Int. J. Heat Mass Transfer, 16, pp. 897-916.
Schade, K. W., and D. M. McEligot, 1971. Cartesian Graetz problems with air property variation. Int. J. Heat Mass Transfer, 14, pp. 653-666.
White, W. D., and D. M. McEligot, 1970. Transition of dilute aqueous polymer mixtures in small tubes. J. Basic Eng., 92, pp. 411-418.
Bankston, C. A., and D. M. McEligot, 1970. Turbulent and laminar heat transfer to gases with varying properties in the entry region of circular ducts. Int. J. Heat Mass Transfer, 13, pp. 319-344.
McEligot, D. M., C. W. Coon and H. C. Perkins, 1970. Relaminarization in tubes. Int. J. Heat Mass Transfer, 13, pp. 431-433.
White, W. D., and D. M. McEligot, 1970. Transition of dilute aqueous polymer mixtures in small tubes. J. Basic Eng., 92, pp. 411-418.
Bankston, C. A., and D. M. McEligot, 1969. Prediction of tube temperatures with axial variation of heating rate and gas property variation. Nuc. Sci. Eng., 37, pp. 157-162.
McEligot, D. M., L. W. Ormand and H. C. Perkins, 1966. Internal low Reynolds number turbulent and transitional gas flow with heat transfer. J. Heat Transfer, 88, pp. 239-245.
McEligot, D. M., P. M. Magee and G. Leppert, 1965. Effect of large temperature gradients on convective heat transfer: The downstream region. J. Heat Transfer, 87, pp. 67-76.