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Ivo Nezbeda 1,2 , Ariel A. Chialvo 3,2 , and Peter T. Cummings 2,3

Effect of the Range of Interactions on the Properties of Fluids Equilibria of CO 2 , Acetone, Methanol and Water. Ivo Nezbeda 1,2 , Ariel A. Chialvo 3,2 , and Peter T. Cummings 2,3 1 Institute of Chemical Process Fundamentals. Academic of Sciences, 16502 Prague 6 - Suchdol, Czech Republic

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Ivo Nezbeda 1,2 , Ariel A. Chialvo 3,2 , and Peter T. Cummings 2,3

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  1. Effect of the Range of Interactionson the Properties of FluidsEquilibria of CO2, Acetone, Methanol and Water Ivo Nezbeda 1,2, Ariel A. Chialvo 3,2, and Peter T. Cummings 2,3 1 Institute of Chemical Process Fundamentals. Academic of Sciences, 16502 Prague 6 - Suchdol, Czech Republic 2Departments of Chemical Engineering. University of Tennessee, Knoxville, TN 37996-2200, U.S.A. 3 Chemical Sciences Division. Oak Ridge National Laboratory, Oak Ridge, TN 37881-6110, U.S.A.

  2. Rationale • Generally long-range forces have negligible effect on the microstructure of fluids • the structure of realistic model fluids and their short-range counterpart are (for all practical purposes) identical • Thermodynamic properties of fluids are accurately estimated by those of the short-range model counterparts • e.g., configurational energy of the short-range models account for 95% of the total property • Long-range forces affect only details of the orientational correlations • however, the dielectric constant remains unaffected • These findings support the development of fast converging perturbation expansions about the short-range reference • i.e., long-range Coulombic interactions treated as a perturbation

  3. Goals • Determine the effect of the long-range Coulombic interactions on the vapor-liquid equilibria properties of polar and associating fluids • most realistic intermolecular potential models available • carbon dioxide, acetone, methanol, and water • Interpret simulation results and develop simple perturbation approaches for rigorous modeling • modeling of aqueous solutions without resorting to long-range interactions • e.g., I. Nezbeda, Mol. Phys., 99, 1631-1639 (2001) • truly molecular-based equation of state for engineering calculations • e.g., recently proposed equation for water (Nezbeda & Weingerl, Mol. Phys., 99, 1595-1606 (2001))

  4. Range of Intermolecular Interactions • Basic definitions • Separation between short- and long-range potential interaction

  5. Range of Intermolecular Interactions • Basic definitions • Switching function for the range transition (e.g., rss=rOO for the case of water and methanol)

  6. Range of Intermolecular Interactions • Simulation details • VLE simulations by NVT-GEMC • Isochoric simulations by NVT-MD • 516<N<700 for GEMC • N=500 for MD • cutoff distance ~ 3.6-5.0 sss (i.e., ~12-19Å) • electrostatics via reaction field • Nosé thermostat for MD • quaternion dynamics • [rL, rU] chosen according to the location of the first peak of the RDF for the reference sites

  7. Vapor-Liquid Equilibrium of Model Carbon Dioxide • Harris-Yung’s EPM2 model (*) • Estimated critical conditions from Wegner expansion • Short-range potential: Tc=310.8K, rc=458.6kg/m3 • Full potential: Tc=310.9K, rc=455.1kg/m3 (*) Harris and Yung, JCP, 99 (1995)

  8. Vapor-Liquid Equilibrium of Model Acetone • Jedlovszky-Pálinkás model (*) • Estimated critical conditions from Wegner expansion • Short-range potential: Tc=505.5K, rc=275.0kg/m3 • Full potential: Tc=499.3K, rc=273.3kg/m3 (*) Jedlovszky and Pálinkás, Mol. Phys., 84 (1995)

  9. Vapor-Liquid Equilibrium of Model Methanol • OPLS model (*) • Estimated critical conditions from Wegner expansion • Short-range potential: Tc=483.4K, rc=250.2kg/m3 • Full potential: Tc=484.6K, rc=258.2kg/m3 (*)Jorgensen et al., JACS, 106 (1984)

  10. Vapor-Liquid Equilibrium of Model Water • TIP4P model (*) • Estimated critical conditions from Wegner expansion • Short-range potential: Tc=564.9K, rc=339.4kg/m3 • Full potential: Tc=566.1K, rc=321.8kg/m3 (*) Jorgensen, JCP, 77 (1982)

  11. Vapor-Liquid Equilibrium • Effect of range on vapor pressure (*) (*) Nezbeda et al., (2001)

  12. Structure and Thermodynamics of Model Methanol • Effect of range on properties along isochore r=0.76g/cc (*) (*) Nezbeda et al. (2001)

  13. Structure and Thermodynamics of Model Methanol • Effect of range on structure along isochore r=0.76g/cc (*) T=298K (*) Nezbeda et al. (2001)

  14. Structure and Thermodynamics of Model Methanol • Effect of range on structure along isochore r=0.76g/cc (*) T=548K (*) Nezbeda et al. (2001)

  15. Interpretation of Simulation Results • Gibbs-Duhem equations including force-field variables (*) • Define coupling parameter l, i.e., • Apply equilibrium conditions • Derive Clapeyron equation (*) Nezbeda et al. (2001)

  16. Interpretation of Simulation Results • Gibbs-Duhem equations including force-field variables (*) • Particular cases can be derived depending on relative sizes of the involved properties in each phase • typical case (water and acetone) • additional cases apply to carbon dioxide and methanol (*) Nezbeda et al. (2001)

  17. Summary and Final Remarks • Spatial and orientational distributions of molecules are marginally affected by long-range forces • Long-range forces affect details of the orientational ordering at short-range distances. • orientational correlations in the short- and full-range systems are qualitatively similar • integrals over these correlations, e.g., dielectric constant, do not differ significantly • Similar behavior is found in the dependence of thermodynamic properties, i.e., energy and pressure, on the range of the potential

  18. Summary and Final Remarks • Critical conditions appear to be unaffected by the long-range forces • These findings lend support to the use of perturbation expansion in the development of truly molecular-based equations of state

  19. Acknowledgements • Research Support • Grant Agency of the Czech Republic (Grant No 203/99/0134) • Division of Chemical Sciences, Geosciences, and Biosciences, Office of Basic Energy Sciences, U.S. Department of Energy under contract number DE-AC05-00OR22725 with Oak Ridge National Laboratory, managed and operated by UT-Battelle, LLC • For more info visit our web_sites • http://www.icpf.cas.cz/theory/IvoNez.html • http://www.ornl.gov/divisions/casd • http://flory.engr.utk.edu/~aac

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