All Stories

  1. The determination of turbulence-model statistics from the velocity–acceleration correlation

    Article • Journal of Fluid Mechanics, September 2014, Cambridge University Press

    Professor Stephen B Pope

  2. Effects of combined dimension reduction and tabulation on the simulations of a turbulent premixed flame using a large-eddy simulation/probability density function method

    Article • Combustion Theory and Modelling, May 2014, Taylor & Francis

    Professor Stephen B Pope

  3. Implicit and explicit schemes for mass consistency preservation in hybrid particle/finite-volume algorithms for turbulent reactive flows

    Article • Journal of Computational Physics, January 2014, Elsevier

    Professor Stephen B Pope

  4. An investigation of mixing in a three-stream turbulent jet

    Article • Physics of Fluids, October 2013, American Institute of Physics

    Professor Stephen B Pope

  5. A model for turbulent mixing based on shadow-position conditioning

    Article • Physics of Fluids, August 2013, American Institute of Physics

    Professor Stephen B Pope

  6. Computational study of lean premixed turbulent flames using RANSPDF and LESPDF methods

    Article • Combustion Theory and Modelling, August 2013, Taylor & Francis

    Professor Stephen B Pope

  7. Simulations of a turbulent non-premixed flame using combined dimension reduction and tabulation for combustion chemistry

    Article • Fuel, March 2013, Elsevier

    Professor Stephen B Pope

  8. A novel transient turbulent jet flame for studying turbulent combustion

    Article • Proceedings of the Combustion Institute, January 2013, Elsevier

    Professor Stephen B Pope

  9. Small scales, many species and the manifold challenges of turbulent combustion

    Article • Proceedings of the Combustion Institute, January 2013, Elsevier

    Professor Stephen B Pope

  10. Large-scale parallel simulations of turbulent combustion using combined dimension reduction and tabulation of chemistry

    Article • Proceedings of the Combustion Institute, January 2013, Elsevier

    Professor Stephen B Pope

  11. Computationally-efficient and scalable parallel implementation of chemistry in simulations of turbulent combustion

    Article • Combustion and Flame, October 2012, Elsevier

    Professor Stephen B Pope

  12. EPVS-FMDF for LES of High-Speed Turbulent Flows

    Article • January 2012, American Institute of Aeronautics and Astronautics (AIAA)

    Professor Stephen B Pope

  13. Turbulent piloted partially-premixed flames with varying levels of O2/N2: stability limits and PDF calculations

    Article • Combustion Theory and Modelling, December 2011, Taylor & Francis

    Professor Stephen B Pope

  14. Numerical implementation of mixing and molecular transport in LES/PDF studies of turbulent reacting flows

    Article • Journal of Computational Physics, July 2011, Elsevier

    Professor Stephen B Pope

  15. Simple models of turbulent flows

    Article • Physics of Fluids, January 2011, American Institute of Physics

    Professor Stephen B Pope

  16. Large eddy simulation/probability density function modeling of a turbulent CH

    Article • Proceedings of the Combustion Institute, January 2011, Elsevier

    Professor Stephen B Pope

  17. Transported Probability Density Function Methods for Reynolds-Averaged and Large-Eddy Simulations

    Article • January 2011, Springer Science + Business Media

    Professor Stephen B Pope

  18. Self-conditioned fields for large-eddy simulations of turbulent flows

    Article • Journal of Fluid Mechanics, April 2010, Cambridge University Press

    Professor Stephen B Pope

  19. Frequency-velocity-scalar filtered mass density function for large eddy simulation of turbulent flows

    Article • Physics of Fluids, July 2009, American Institute of Physics

    Professor Stephen B Pope

  20. Sensitivity calculations in PDF modelling of turbulent flames

    Article • Proceedings of the Combustion Institute, January 2009, Elsevier

    Professor Stephen B Pope

  21. Turbulent dispersion from line sources in grid turbulence

    Article • Physics of Fluids, October 2008, American Institute of Physics

    Professor Stephen B Pope

  22. Lagrangian investigation of local extinction, re-ignition and auto-ignition in turbulent flames

    Article • Combustion Theory and Modelling, September 2008, Taylor & Francis

    Professor Stephen B Pope

  23. Universal Intermittent Properties of Particle Trajectories in Highly Turbulent Flows

    Article • Physical Review Letters, June 2008, American Physical Society (APS)

    Professor Stephen B Pope

  24. Time-averaging strategies in the finite-volume/particle hybrid algorithm for the joint PDF equation of turbulent reactive flows

    Article • Combustion Theory and Modelling, May 2008, Taylor & Francis

    Professor Stephen B Pope

  25. Transport budgets in turbulent lifted flames of methane autoigniting in a vitiated co-flow

    Article • Combustion and Flame, November 2007, Elsevier

    Professor Stephen B Pope

  26. Velocity-scalar filtered mass density function for large eddy simulation of turbulent reacting flows

    Article • Physics of Fluids, September 2007, American Institute of Physics

    Professor Stephen B Pope

  27. A numerical study of auto-ignition in turbulent lifted flames issuing into a vitiated co-flow

    Article • Combustion Theory and Modelling, April 2007, Taylor & Francis

    Professor Stephen B Pope

  28. Comparative study of micromixing models in transported scalar PDF simulations of turbulent nonpremixed bluff body flames

    Article • Combustion and Flame, July 2006, Elsevier

    Professor Stephen B Pope

  29. Computational Modeling of Turbulent Flames

    Article • December 2005, World Scientific Pub Co Pte Lt

    Professor Stephen B Pope

  30. The performance ofin situadaptive tabulation in computations of turbulent flames

    Article • Combustion Theory and Modelling, November 2005, Taylor & Francis

    Professor Stephen B Pope

  31. Turbulent lifted flames in a vitiated coflow investigated using joint PDF calculations

    Article • Combustion and Flame, September 2005, Elsevier

    Professor Stephen B Pope

  32. Paradigms in turbulent combustion research

    Article • Proceedings of the Combustion Institute, January 2005, Elsevier

    Professor Stephen B Pope

  33. Large eddy simulation of a turbulent nonpremixed piloted methane jet flame (Sandia Flame D)

    Article • Proceedings of the Combustion Institute, January 2005, Elsevier

    Professor Stephen B Pope

  34. Computational Models for Turbulent Reacting Flows. By R. O. FOX. Cambridge University Press, 2003. 438 pp. ISBN 0521 650496, 80 or $120 (hardback); ISBN 0521 6590780, 39.95 or $55 (paperback)

    Article • Journal of Fluid Mechanics, April 2004, Cambridge University Press

    Professor Stephen B Pope

  35. Ten questions concerning the large-eddy simulation of turbulent flows

    Article • New Journal of Physics, March 2004, Institute of Physics Publishing

    Professor Stephen B Pope

  36. Pdf calculations of turbulent lifted flames of H2/N2fuel issuing into a vitiated co-flow

    Article • Combustion Theory and Modelling, March 2004, Taylor & Francis

    Professor Stephen B Pope

  37. An investigation of the performance of turbulent mixing models

    Article • Combustion and Flame, January 2004, Elsevier

    Professor Stephen B Pope, Zhuyin Ren

  38. Accessed Compositions in Turbulent Reactive Flows

    Article • Flow Turbulence and Combustion, January 2004, Springer Science + Business Media

    Professor Stephen B Pope

  39. Velocity-scalar filtered density function for large eddy simulation of turbulent flows

    Article • Physics of Fluids, August 2003, American Institute of Physics

    Professor Stephen B Pope

  40. The modeling of turbulent reactive flows based on multiple mapping conditioning

    Article • Physics of Fluids, June 2003, American Institute of Physics

    Professor Stephen B Pope

  41. Erratum: “A stochastic Lagrangian model for acceleration in turbulent flows” [Phys. Fluids 14, 2360 (2002)]

    Article • Physics of Fluids, January 2003, American Institute of Physics

    Professor Stephen B Pope

  42. A stochastic Lagrangian model for acceleration in turbulent flows

    Article • Physics of Fluids, July 2002, American Institute of Physics

    Professor Stephen B Pope

  43. Stochastic Lagrangian models of velocity in homogeneous turbulent shear flow

    Article • Physics of Fluids, May 2002, American Institute of Physics

    Professor Stephen B Pope

  44. The Hybrid Method for the PDF Equations of Turbulent Reactive Flows: Consistency Conditions and Correction Algorithms

    Article • Journal of Computational Physics, May 2002, Elsevier

    Professor Stephen B Pope

  45. Velocity filtered density function for large eddy simulation of turbulent flows

    Article • Physics of Fluids, March 2002, American Institute of Physics

    Professor Stephen B Pope

  46. The Hybrid Method for the PDF Equations of Turbulent Reactive Flows: Consistency Conditions and Correction Algorithms

    Article • Journal of Computational Physics, September 2001, Elsevier

    Professor Stephen B Pope

  47. A Hybrid Algorithm for the Joint PDF Equation of Turbulent Reactive Flows

    Article • Journal of Computational Physics, January 2001, Elsevier

    Professor Stephen B Pope

  48. PDF calculations of turbulent nonpremixed flames with local extinction

    Article • Combustion and Flame, November 2000, Elsevier

    Professor Stephen B Pope

  49. Turbulent Flows

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  50. Preface

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  51. Introduction

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  52. Wall flows

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  53. Diffusion processes

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  54. Characteristic functions

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  55. Bibliography

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  56. Nomenclature

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  57. Fourier transforms

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  58. PDF methods

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  59. Cartesian tensors

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  60. Reynolds-stress and related models

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  61. Direct numerical simulation

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  62. An introduction to modelling and simulation

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  63. Free shear flows

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  64. Mean-flow equations

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  65. Turbulent-viscosity models

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  66. The scales of turbulent motion

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  67. The statistical description of turbulent flows

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  68. The equations of fluid motion

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  69. Spectral representation of stationary random processes

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  70. Properties of second-order tensors

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  71. Power-law spectra

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  72. Large-eddy simulation

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  73. The discrete Fourier transform

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  74. Dirac delta functions

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  75. Derivation of Eulerian PDF equations

    Article • August 2000, Cambridge University Press

    Professor Stephen B Pope

  76. Probability density function calculations of local extinction and no production in piloted-jet turbulent methane/air flames

    Article • Proceedings of the Combustion Institute, January 2000, Elsevier

    Professor Stephen B Pope

  77. Filtered mass density function for large-eddy simulation of turbulent reacting flows

    Article • Journal of Fluid Mechanics, December 1999, Cambridge University Press

    Professor Stephen B Pope

  78. A Consistent Hybrid Finite-Volume/Particle Method for the PDF Equations of Turbulent Reactive Flows

    Article • Journal of Computational Physics, September 1999, Elsevier

    Professor Stephen B Pope

  79. Comparison of mixing model performance for nonpremixed turbulent reactive flow

    Article • Combustion and Flame, June 1999, Elsevier

    Professor Stephen B Pope

  80. Assessment of Numerical Accuracy of PDF/Monte Carlo Methods for Turbulent Reacting Flows

    Article • Journal of Computational Physics, June 1999, Elsevier

    Professor Stephen B Pope

  81. Direct numerical simulation of a statistically stationary, turbulent reacting flow

    Article • Combustion Theory and Modelling, June 1999, Taylor & Francis

    Professor Stephen B Pope

  82. PDF simulations of turbulent combustion incorporating detailed chemistry

    Article • Combustion and Flame, April 1999, Elsevier

    Professor Stephen B Pope

  83. A Perspective on Turbulence Modeling

    Article • January 1999, Springer Science + Business Media

    Professor Stephen B Pope

  84. The vanishing effect of molecular diffusivity on turbulent dispersion: implications for turbulent mixing and the scalar flux

    Article • Journal of Fluid Mechanics, March 1998, Cambridge University Press

    Professor Stephen B Pope

  85. Probability density function/Monte Carlo simulation of near-wall turbulent flows

    Article • Journal of Fluid Mechanics, February 1998, Cambridge University Press

    Professor Stephen B Pope

  86. Calculations of subsonic and supersonic turbulent reacting mixing layers using probability density function methods

    Article • Physics of Fluids, February 1998, American Institute of Physics

    Professor Stephen B Pope

  87. Filtered density function for large eddy simulation of turbulent reacting flows

    Article • Physics of Fluids, February 1998, American Institute of Physics

    Professor Stephen B Pope

  88. Advances in PDF modeling for inhomogeneous turbulent flows

    Article • Physics of Fluids, January 1998, American Institute of Physics

    Professor Stephen B Pope

  89. PDF calculations of major and minor species in a turbulent piloted jet flame

    Article • Symposium (International) on Combustion, January 1998, Elsevier

    Professor Stephen B Pope

  90. Application of PDF methods to compressible turbulent flows

    Article • Physics of Fluids, September 1997, American Institute of Physics

    Professor Stephen B Pope

  91. Wall-function treatment in pdf methods for turbulent flows

    Article • Physics of Fluids, September 1997, American Institute of Physics

    Professor Stephen B Pope

  92. PDF Model Calculations of Compressible Turbulent Flows Using Smoothed Particle Hydrodynamics

    Article • Journal of Computational Physics, June 1997, Elsevier

    Professor Stephen B Pope

  93. Probability density function and Reynolds-stress modeling of near-wall turbulent flows

    Article • Physics of Fluids, January 1997, American Institute of Physics

    Professor Stephen B Pope

  94. A DNS study of turbulent mixing of two passive scalars

    Article • Physics of Fluids, August 1996, American Institute of Physics

    Professor Stephen B Pope

  95. An integrated PDF/neural network approach for simulating turbulent reacting systems

    Article • Symposium (International) on Combustion, January 1996, Elsevier

    Professor Stephen B Pope

  96. A mixing model to improve the PDF simulation of turbulent diffusion flames

    Article • Symposium (International) on Combustion, January 1996, Elsevier

    Professor Stephen B Pope

  97. Particle Method for Turbulent Flows: Integration of Stochastic Model Equations

    Article • Journal of Computational Physics, March 1995, Elsevier

    Professor Stephen B Pope

  98. A PDF-based particle method for compressible turbulent flows

    Article • January 1995, American Institute of Aeronautics and Astronautics (AIAA)

    Professor Stephen B Pope

  99. Modeling of extinction in turbulent diffusion flames by the velocity-dissipation-composition PDF method

    Article • Combustion and Flame, January 1995, Elsevier

    Professor Stephen B Pope

  100. Lagrangian PDF Methods for Turbulent Flows

    Article • Annual Review of Fluid Mechanics, January 1994, Annual Reviews

    Professor Stephen B Pope

  101. PDF calculations of turbulent nonpremixed flames of using reduced chemical mechanisms

    Article • Combustion and Flame, October 1993, Elsevier

    Professor Stephen B Pope

  102. Reaction and diffusion in turbulent combustion. Progress report

    Article • June 1993, Office of Scientific and Technical Information (OSTI)

    Professor Stephen B Pope

  103. PDF/Monte Carlo Methods for Turbulent Combustion and Their Implementation on Parallel Computers

    Article • January 1993, Elsevier

    Professor Stephen B Pope

  104. Reaction and diffusion in turbulent combustion

    Article • October 1992, Office of Scientific and Technical Information (OSTI)

    Professor Stephen B Pope

  105. Reaction and diffusion in turbulent combustion. Progress report

    Article • October 1992, Office of Scientific and Technical Information (OSTI)

    Professor Stephen B Pope

  106. Erratum: ‘‘Application of the velocity-dissipation probability density function model to inhomogeneous turbulent flows’’ [Phys. Fluids A 3, 1947 (1991)]

    Article • Physics of Fluids A Fluid Dynamics, May 1992, American Institute of Physics

    Professor Stephen B Pope

  107. Mapping Closures for Turbulent Mixing and Reaction

    Article • January 1992, Springer Science + Business Media

    Professor Stephen B Pope

  108. Reaction and diffusion in turbulent combustion

    Article • October 1991, Office of Scientific and Technical Information (OSTI)

    Professor Stephen B Pope

  109. Reaction and diffusion in turbulent combustion. Progress report

    Article • October 1991, Office of Scientific and Technical Information (OSTI)

    Professor Stephen B Pope

  110. Mapping closures for turbulent mixing and reaction

    Article • Theoretical and Computational Fluid Dynamics, August 1991, Springer Science + Business Media

    Professor Stephen B Pope

  111. Application of the velocity-dissipation probability density function model to inhomogeneous turbulent flows

    Article • Physics of Fluids A Fluid Dynamics, August 1991, American Institute of Physics

    Professor Stephen B Pope

  112. Turbulent mixing model based on ordered pairing

    Article • Combustion and Flame, January 1991, Elsevier

    Professor Stephen B Pope

  113. Computations of turbulent combustion: Progress and challenges

    Article • Symposium (International) on Combustion, January 1991, Elsevier

    Professor Stephen B Pope

  114. Modelling of flamelet surface-to-volume ratio in turbulent premixed combustion

    Article • Symposium (International) on Combustion, January 1991, Elsevier

    Professor Stephen B Pope

  115. The velocity-dissipation probability density function model for turbulent flows

    Article • Physics of Fluids A Fluid Dynamics, August 1990, American Institute of Physics

    Professor Stephen B Pope

  116. PDF calculations of piloted turbulent nonpremixed flames of methane

    Article • Combustion and Flame, July 1990, Elsevier

    Professor Stephen B Pope

  117. A PDF Method for Turbulent Recirculating Flows

    Article • January 1989, Springer Science + Business Media

    Professor Stephen B Pope

  118. The stochastic flamelet model of turbulent premixed combustion

    Article • Symposium (International) on Combustion, January 1989, Elsevier

    Professor Stephen B Pope

  119. The evolution equation of joint Pdf of turbulent velocity and dissipation

    Article • Applied Mathematics and Mechanics, January 1989, Springer Science + Business Media

    Professor Stephen B Pope

  120. The importance of time-dependent flame structures in stretched laminar flamelet models for turbulent jet diffusion flames

    Article • Symposium (International) on Combustion, January 1989, Elsevier

    Professor Stephen B Pope

  121. Assessment of a partial-equilibrium/monte carlo model for turbulent syngas flames

    Article • Combustion and Flame, May 1988, Elsevier

    Professor Stephen B Pope

  122. Direct numerical simulations of the turbulent mixing of a passive scalar

    Article • The Physics of Fluids, March 1988, American Institute of Physics

    Professor Stephen B Pope

  123. Joint PDF calculations of a non-equilibrium turbulent diffusion flame

    Article • Symposium (International) on Combustion, January 1988, Elsevier

    Professor Stephen B Pope

  124. Monte Carlo solutions of a joint PDF equation for turbulent flows in general orthogonal coordinates

    Article • Journal of Computational Physics, October 1987, Elsevier

    Professor Stephen B Pope

  125. Consistency conditions for random-walk models of turbulent dispersion

    Article • The Physics of Fluids, August 1987, American Institute of Physics

    Professor Stephen B Pope

  126. A pdf modeling study of self-similar turbulent free shear flows

    Article • The Physics of Fluids, April 1987, American Institute of Physics

    Professor Stephen B Pope

  127. Calculations of premixed turbulent flames by PDF methods

    Article • Combustion and Flame, February 1987, Elsevier

    Professor Stephen B Pope

  128. Turbulent Premixed Flames

    Article • Annual Review of Fluid Mechanics, January 1987, Annual Reviews

    Professor Stephen B Pope

  129. The Mixing Layer Between Turbulent Fields of Different Scales

    Article • January 1987, Springer Science + Business Media

    Professor Stephen B Pope

  130. A generalized Langevin model for turbulent flows

    Article • The Physics of Fluids, February 1986, American Institute of Physics

    Professor Stephen B Pope

  131. Lagrangian Modelling for Turbulent Flows

    Article • January 1985, Springer Science + Business Media

    Professor Stephen B Pope

  132. Diffusion Behind a Line Source in Grid Turbulence

    Article • January 1985, Springer Science + Business Media

    Professor Stephen B Pope

  133. PDF methods for turbulent reactive flows

    Article • Progress in Energy and Combustion Science, January 1985, Elsevier

    Professor Stephen B Pope

  134. Flamelet and distributed combustion in premixed turbulent flames

    Article • Symposium (International) on Combustion, January 1985, Elsevier

    Professor Stephen B Pope

  135. Monte Carlo Calculations of Turbulent Diffusion Flames

    Article • Combustion Science and Technology, December 1984, Taylor & Francis

    Professor Stephen B Pope

  136. Calculations of a Plane Turbulent Jet

    Article • AIAA Journal, July 1984, American Institute of Aeronautics and Astronautics (AIAA)

    Professor Stephen B Pope

  137. Probability Calculations for Turbulent Jet Flows with Mixing and Reaction of NO and O3

    Article • Combustion Science and Technology, May 1984, Taylor & Francis

    Professor Stephen B Pope

  138. A Lagrangian two-time probability density function equation for inhomogeneous turbulent flows

    Article • The Physics of Fluids, December 1983, American Institute of Physics

    Professor Stephen B Pope

  139. Consistent modeling of scalars in turbulent flows

    Article • The Physics of Fluids, February 1983, American Institute of Physics

    Professor Stephen B Pope

  140. Calculations of a plane turbulent jet

    Article • January 1983, American Institute of Aeronautics and Astronautics (AIAA)

    Professor Stephen B Pope

  141. An Improved Turbulent Mixing Model

    Article • Combustion Science and Technology, June 1982, Taylor & Francis

    Professor Stephen B Pope

  142. Calculations of Velocity-Scalar Joint pdf’s

    Article • January 1982, Springer Science + Business Media

    Professor Stephen B Pope

  143. The Application of PDF Transport Equations to Turbulent Reactive Flows

    Article • Journal of Non-Equilibrium Thermodynamics, January 1982, De Gruyter

    Professor Stephen B Pope

  144. Transport equation for the joint probability density function of velocity and scalars in turbulent flow

    Article • The Physics of Fluids, April 1981, American Institute of Physics

    Professor Stephen B Pope

  145. Monte Carlo calculations of premixed turbulent flames

    Article • Symposium (International) on Combustion, January 1981, Elsevier

    Professor Stephen B Pope

  146. A Monte Carlo Method for the PDF Equations of Turbulent Reactive Flow

    Article • Combustion Science and Technology, January 1981, Taylor & Francis

    Professor Stephen B Pope

  147. The Statistical Theory of Turbulent Flames

    Article • Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences, July 1979, Royal Society Publishing

    Professor Stephen B Pope

  148. A Rational Method of Determining Probability Distributions in Turbulent Reacting Flows

    Article • Journal of Non-Equilibrium Thermodynamics, January 1979, De Gruyter

    Professor Stephen B Pope

  149. Author's reply to C. Dopazo's comments on “The probability approach to the modelling of turbulent reacting flows”

    Article • Combustion and Flame, January 1979, Elsevier

    Professor Stephen B Pope

  150. An explanation of the turbulent round-jet/plane-jet anomaly

    Article • AIAA Journal, March 1978, American Institute of Aeronautics and Astronautics (AIAA)

    Professor Stephen B Pope

  151. The calculation of turbulent recirculating flows in general orthogonal coordinates

    Article • Journal of Computational Physics, February 1978, Elsevier

    Professor Stephen B Pope

  152. The implications of the probability equations for turbulent combustion models

    Article • Combustion and Flame, January 1977, Elsevier

    Professor Stephen B Pope

  153. The probability approach to the modelling of turbulent reacting flows

    Article • Combustion and Flame, August 1976, Elsevier

    Professor Stephen B Pope