AIChE Journal

Cover image for AIChE Journal

March 2007

Volume 53, Issue 3

Pages 542–749

  1. Perspective

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Advances in modeling of polymer melt rheology (pages 542–548)

      Ronald G. Larson, Qiang Zhou, Sachin Shanbhag and Seung Joon Park

      Version of Record online: 21 DEC 2006 | DOI: 10.1002/aic.11064

  2. Fluid Mechanics and Transport Phenomena

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Drying and film formation of industrial waterborne latices (pages 549–560)

      I. Ludwig, W. Schabel, M. Kind, J.-C. Castaing and P. Ferlin

      Version of Record online: 19 JAN 2007 | DOI: 10.1002/aic.11098

    2. Design principles of integrated vacuum slot arrangement (pages 572–578)

      Jyotsna Tanwar, Madhu Vinjamur and L. E. Scriven

      Version of Record online: 2 FEB 2007 | DOI: 10.1002/aic.11112

  3. Particle Technology and Fluidization

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Reverse-flow centrifugal separators in parallel: Performance and flow pattern (pages 589–597)

      Weiming Peng, Alex C. Hoffmann, Huub Dries, Michiel Regelink and Kee-Khoon Foo

      Version of Record online: 2 FEB 2007 | DOI: 10.1002/aic.11121

  4. Separations

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Filtration model for suspensions that form filter cakes with creep behavior (pages 598–609)

      Morten Lykkegaard Christensen and Kristian Keiding

      Version of Record online: 29 JAN 2007 | DOI: 10.1002/aic.11108

    2. Novel Ag+-zeolite/polymer mixed matrix membranes with a high CO2/CH4 selectivity (pages 610–616)

      Yi Li, Tai-Shung Chung and Santi Kulprathipanja

      Version of Record online: 29 JAN 2007 | DOI: 10.1002/aic.11109

    3. Modeling l-dopa purification by chiral ligand-exchange chromatography (pages 617–626)

      Nooshafarin Sanaie and Charles A. Haynes

      Version of Record online: 2 FEB 2007 | DOI: 10.1002/aic.11111

  5. Process Systems Engineering

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Optimal grade transition in industrial polymerization processes via NCO tracking (pages 627–639)

      J. V. Kadam, W. Marquardt, B. Srinivasan and D. Bonvin

      Version of Record online: 6 FEB 2007 | DOI: 10.1002/aic.11085

    2. Dynamic optimization of electric arc furnace operation (pages 640–653)

      Richard D. M. MacRosty and Christopher L. E. Swartz

      Version of Record online: 5 FEB 2007 | DOI: 10.1002/aic.11104

    3. Fault-tolerant control of nonlinear process systems subject to sensor faults (pages 654–668)

      Prashant Mhaskar, Adiwinata Gani, Charles McFall, Panagiotis D. Christofides and James F. Davis

      Version of Record online: 6 FEB 2007 | DOI: 10.1002/aic.11100

  6. Reactors, Kinetics, and Catalysis

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Experimental and modeling of carbonate formation in the effluent of oxygen delignification (pages 669–677)

      D. C. Zhang, J. Hsieh, X.-S. Chai and A. J. Ragauskas

      Version of Record online: 16 JAN 2007 | DOI: 10.1002/aic.11095

    2. Radiation field optimization in photocatalytic monolith reactors for air treatment (pages 678–686)

      Maniraj Singh, Ignasi Salvadó-Estivill and Gianluca Li Puma

      Version of Record online: 19 JAN 2007 | DOI: 10.1002/aic.11093

    3. High surface area titania photocatalytic microfluidic reactors (pages 695–702)

      Henrik Lindstrom, Robert Wootton and Alexander Iles

      Version of Record online: 2 FEB 2007 | DOI: 10.1002/aic.11096

  7. Materials, Interfaces and Electrochemical Phenomena

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

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

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

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Efficient separation coupled with ultrasonic atomization using a molecular sieve (pages 737–740)

      Kazuo Matsuura, Tetsuo Fukazu, Fusatsugu Abe, Taisuke Sekimoto and Toshiro Tomishige

      Version of Record online: 5 FEB 2007 | DOI: 10.1002/aic.11113

  11. Reactors, Kinetics, and Catalysis

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Determination of catalyst wetting fraction on the molecular level (pages 741–745)

      Zhen-Min Cheng, Zhi-Ming Zhou and Wei-Kang Yuan

      Version of Record online: 30 JAN 2007 | DOI: 10.1002/aic.11097

  12. Materials, Interfaces and Electrochemical Phenomena

    1. Top of page
    2. Perspective
    3. Fluid Mechanics and Transport Phenomena
    4. Particle Technology and Fluidization
    5. Separations
    6. Process Systems Engineering
    7. Reactors, Kinetics, and Catalysis
    8. Materials, Interfaces and Electrochemical Phenomena
    9. Thermodynamics
    10. Fluid Mechanics and Transport Phenomena
    11. Separations
    12. Reactors, Kinetics, and Catalysis
    13. Materials, Interfaces and Electrochemical Phenomena
    1. Synthesis of monodisperse carbon beads with developed mesoporosity (pages 746–749)

      Takuji Yamamoto, Akira Endo, Apiluck Eiad-ua, Takao Ohmori, Masaru Nakaiwa and Apinan Soottitantawat

      Version of Record online: 5 FEB 2007 | DOI: 10.1002/aic.11106

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