AIChE Journal

Cover image for AIChE Journal

March 2003

Volume 49, Issue 3

Pages fmi–fmi, 550–804

  1. Masthead

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Masthead (page fmi)

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490301

  2. Perspective

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. New vistas in dispersion science and engineering (pages 550–556)

      Darsh Wasan, Alex Nikolov and Douglas Henderson

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490302

  3. Fluid Mechanics and Transport Phenomena

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Gas–liquid two-phase flow through packed beds in microgravity (pages 557–565)

      Brian J. Motil, Vemuri Balakotaiah and Yasuhiro Kamotani

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490303

    2. Laminar mixing in different interdigital micromixers: I. Experimental characterization (pages 566–577)

      V. Hessel, S. Hardt, H. Löwe and F. Schönfeld

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490304

  4. Particle Technology and Fluidization

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Promotion of deactivated sintering by dry-particle coating (pages 604–618)

      Michelle Ramlakhan Mohan, Rajesh N. Dave and Robert Pfeffer

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490307

    2. Production of carbon nanotubes in a packed bed and a fluidized bed (pages 619–625)

      Qian Weizhong, Wei Fei, Wang Zhanwen, Liu Tang, Yu Hao, Luo Guohua, Xiang Lan and Deng Xiangyi

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490308

  5. Separations

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Mechanics of column beds: I. Acquisition of the relevant parameters (pages 626–641)

      Bee Gaik Yew, Eric C. Drumm and Georges Guiochon

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490309

    2. Mechanics of column beds: II. Modeling of coupled stress-strain-flow behavior (pages 642–664)

      Bee Gaik Yew, Jorge Ureta, R. Andrew Shalliker, Eric C. Drumm and Georges Guiochon

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490310

    3. Positioning of salt gradients in ion-exchange SMB (pages 665–674)

      Joukje Houwing, Thomas B. Jensen, Stef H. van Hateren, Hugo A. H. Billiet and Luuk A. M. van der Wielen

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490311

  6. Process Systems Engineering

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Enhancement of large-particle gas-fluidization by adding liquid (pages 675–681)

      Y. Nagahashi, D. H. Lee, J. R. Grace, N. Epstein, A. Yokogawa and Y. Asako

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490312

    2. Optimal region for design and control of ternary systems (pages 682–705)

      Yu-Chang Cheng and Cheng-Ching Yu

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490313

    3. 2-D wavelet-based adaptive-grid method for the resolution of PDEs (pages 706–717)

      J. C. Santos, P. Cruz, F. D. Magalhães and A. Mendes

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490314

  7. Reactors, Kinetics, and Catalysis

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Water-density effects on phenol oxidation in supercritical water (pages 718–726)

      Jeffrey T. Henrikson and Phillip E. Savage

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490315

    2. Optimum photolysis in Taylor–Couette flow (pages 727–733)

      L. J. Forney and J. A. Pierson

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490316

    3. Performance of immobilized photocatalytic reactors in continuous mode (pages 734–744)

      M. F. J. Dijkstra, E. C. B. Koerts, A. A. C. M. Beenackers and J. A. Wesselingh

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490317

  8. Thermodynamics

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Three-liquid phase equilibria in water+benzene+caprolactam+(NH4)2SO4 mixtures (pages 745–752)

      Zhou Huan, Gerard H. Van Bochove and Theo W. De Loos

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490318

    2. Monte Carlo simulation of adsorption using 2-D models of heterogeneous solids (pages 753–763)

      V. F. Cabral, F. W. Tavares and M. Castier

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490319

    3. Thermal machines based on surface energy of wetting: Thermodynamic analysis (pages 764–781)

      A. Laouir, L. Luo, D. Tondeur, T. Cachot and P. Le Goff

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490320

  9. Environmental and Energy Engineering

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Physical model analysis of foam–TCE displacement in porous media (pages 782–788)

      Seung-Woo Jeong and M. Yavuz Corapcioglu

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490321

  10. Fluid Mechanics and Transport Phenomena

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
  11. Separations

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
  12. Thermodynamics

    1. Top of page
    2. Masthead
    3. Perspective
    4. Fluid Mechanics and Transport Phenomena
    5. Particle Technology and Fluidization
    6. Separations
    7. Process Systems Engineering
    8. Reactors, Kinetics, and Catalysis
    9. Thermodynamics
    10. Environmental and Energy Engineering
    11. Fluid Mechanics and Transport Phenomena
    12. Separations
    13. Thermodynamics
    1. Viscosity model for pure liquids based on Eyring theory and cubic EOS (pages 799–804)

      Ricardo Macías-Salinas, Fernando García-Sánchez and Otilio Hernández-Garduza

      Version of Record online: 16 APR 2004 | DOI: 10.1002/aic.690490324

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