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Robert D. Moser

Dr. Robert D. Moser earned his Ph.D. in mechanical engineering from Stanford University in 1984. He joined the faculty of The University of Texas at Austin in 2005. Dr. Moser is a faculty member of the Thermal and Fluid Systems program, and serves as the area coordinator for that program. Dr. Moser is also a faculty member in the Institute for Computational Engineering and Sciences, where he is serving as Deputy Director. Finally, Dr. Moser is the Director of the DOE-funded Center for Predictive Engineering and Computational Sciences (PECOS).

Using computer simulations, Moser develops techniques to predict and control the effects of turbulence and other complex flows. He attempts to improve the turbulence-prediction abilities of large-eddy simulation techniques, which simulate the effects of the most energetic turbulence eddies while modeling the effects of smaller-scale turbulence. He also uses large-eddy simulation techniques to model external aerodynamic flows. Computer simulation is also valuable to study biological flows. Moser is developing computer models of the human cardiovascular system, at both macroscopic and microscopic scales, for use in the development and evaluation of new therapies. Finally, in numerical simulations of complex physical systems, the uncertainties inherent in such systems need to be characterized, and Moser is working to develop methods to quantify such uncertainties, especially in the context of reentry vehicle simulations.

Research interests:

  • Turbulence physics
  • Direct numerical simulation and spectral methods
  • Large-eddy simulation
  • Cardiovascular fluid mechanics
  • Verification, validation and uncertainty quantification in computational science.

Most Recent Publications

  1. Todd A. Oliver and Robert D. Moser, "Accounting for uncertainty in the analysis of overlap layer mean velocity models," Physics Of Fluids, Vol. 24, (2012), 7, pp. 75-108
  2. S. K. Jee & R. D. Moser, "Conservative integral form of the incompressible Navier-Stokes equations for a rapidly pitching airfoil," Journal Of Computational Physics, Vol. 231, (2012), pp. 6268-6289
  3. S. Yang, G. Stadler, R. Moser & O. Ghattas, "A Shape Hessian-Based Boundary Roughness Analysis of Navier--{S}tokes Flow," SIAM Journal On Applied Mathematics, Vol. 71, (2011), pp. 333-355
  4. Lopez Meji, OD; Moser, RD; Brzozowski, DP; Glezer, A, "Effects of Trailing-Edge Synthetic Jet Actuation on an Airfoil," AIAA Journal, Vol. 49, (2011), pp. 1763-1777
  5. Cheung, SH; Oliver, TA; Prudencio, EE1; Prudhomme, S ; Moser, RD , "Bayesian uncertainty analysis with applications to turbulence modeling ," Reliability Engineering And System Safety, Vol. 96, (2011), pp. 1137-1149
  6. A. Haselbacher, F. M. Najjar, L. Massa, R. D. Moser, "Slow-time acceleration for modeling multiple-time-scale problems," J. Comput. Phys., (2010), 229, pp. 325-342
  7. Moser, R. D., Malaya, N. P., Chang, H., Zandonade, P. S., Vedula, P., Bhattacharya, A. & Haselbacher, A., "Theoretically based optimal large-eddy simulation," Phys. Of Fluids, (2009), 21, pp. 105104
  8. Bazilevs Y., Gohean J. R., Hughes T. J. R., Moser, R. D. & Zhang, Y., "Patientspecific isogeometric fluid-structure interaction analysis of thoracic aortic blood flow due to implantation of the Jarvik 2000 left ventricular assist device," Comp. Meth. In Applied Mech. And Eng., (2009), 198, pp. 3534-3550
  9. A. Bhattacharya, S. C. Kassinos & R. D. Moser, "Representing anisotropy of two-point second-order turbulence velocity correlations using structure tensors," Physics Of Fluids, Vol. 20, (2008), 10, pp. Article Number: 101502
  10. Bhattacharya A, Das A, Moser RD , " A filtered-wall formulation for large-eddy simulation of wall-bounded turbulence ," Phys. Of Fluids, Vol. 20, (2008), 11, pp. Article Number: 115104