Difference between revisions of "Thermodynamics"

OLI Thermodynamics and Concepts section will help provide users with an insight about basic concepts OLI software and the engine is built on.

General Thermodynamics and Fundamentals

• Calculation of pH in multiple solvents
• Conversion of Assays and Pseudo-components to OLI Species
• Electrical Conductivity and Ionic Radii
• H3OION in MSE databank
• Development of the Hydronium Ion for MSE
• Why is the Gibbs Free Energy of Formation for the Hydrogen Ion not zero?
• Heat Capacity
• How is pH calculated when there is no H ion?
• MSE Density Parameter Update
• What is a "BINTER"?
• x-based and m-based activity coefficients in the solver
• Converting mole fraction based equilibrium constants to molality based values
• Electrolytes and Activity Coefficients
• Self-diffusivity
• Total Dissolved Solids (TDS)
• Comparing activity coefficients between different thermodynamic frameworks
• Scale Inhibition
• MSE-SRK

OLI Modeling

• How to calculate fugacities when no vapor phase is present
• How to "Set" the partial pressure of a gas?
• Reaction Kinetics Overview in OLI Software (PDF, 2.5 MB, TIPS #80)
• Scaling Tendencies
  • Pre-scaling Tendencies
• Sparingly Soluble Organics
• Volumes vs. Standard Volumes vs. Standard Liquid Volumes
• TRANGE
• True Species vs Apparent species
• Relative Humidity
• Fixed, point and parent stream conditions - Definitions

Data Regression

• ASAP variable list
• Mixed Solvent Electrolyte ( MSE) model Regression Parameters
• Traditional Regression Parameters
• What is the SOLU parameter?
• Using Stability Constants (Equilibrium Constants) with the OLI Databook (PDF)

OLI Papers and Presentations on Thermodynamics

• Anderko, Andrej, Lencka, Malgorzata. "Computation of Electrical Conductivity of Multi component Aqueous Systems in Wide Concentration and Temperature Ranges. Ind. Eng.Chem.Res. 1997, 36, 1932-1943
• Anderko, A., Wang, P., & Rafal, M. (2002). Electrolyte solutions: from thermodynamic and transport property models to the simulation of industrial processes. Fluid Phase Equilibria, 194-197, 123-142.
• Kosinski, J. J., Wang, P., Springer, R. D., & Anderko, A. (2007). Modeling acid–base equilibria and phase behavior in mixed-solvent electrolyte systems. Fluid Phase Equilibria, 256, 34-41
• Lencka, Malgorzata M., Jerzy J. Kosinski, Peiming Wang, Andrzej Anderko. Thermodynamic modeling of aqueous systems containing amines and amine hydrochlorides: Application to methylamine, morpholine, and morpholine derivatives. Fluid Phase Equilibria 418 (2016) 160-174
• Lencka, Malgorzata M., Richard E. Riman, "Thermodynamic Modeling of Hydrothermal Synthesis of Ceramic Powders." Chem. Mater. 1993, 5, 61-70.
• Lencka, Malgorzata M., Richard E. Riman, "Thermodynamic Modeling of Hydrotehrmal Synthsis of Calcium Titanate with Reference to Other Alkaline-Earth Titanates." Chem. Mater. 1995, 7, 18-25.
• Lencka, Malgorzata M., Magdalena Oledzka, Richard E. Riman, "Hydrothermal Synthesis of Sodium and Potassium Bismuth Titanates." Chem. Mater. 2000, 12, 1323-1330
• Nimkar, R., Simulating refining overhead chemistry in Pro/II. Presented at the SimSci User Conference Pasadena, California September 2016
• Springer, R. D., Wang, Z., Anderko, A., Wang, P., & Felmy, A. R. (2012). A thermodynamic model for predicting mineral reactivity in supercritical carbon dioxide: I. Phase behavior of carbon dioxide–water–chloride salt systems across the H2O-rich to the CO2-rich regions. Chemical Geology, 322-323, 151-171.
• Rafal, M., Berthold, J. W., Scrivner, N. C., & Grise, S. L. (1994). Models for Electrolyte Solutions. In S. I. Sandler, Models for Thermodynamic and Phase Equilibrium Calculations (p. 686). New York: Marcel Dekker, Inc.
• Wang, P., & Anderko, A. (2008). Modeling Thermal Conductivity of Concentrated and Mixed-Solvent Electrolyte Systems. Ind. Eng. chem. Res, 47, 5698-5709.
• Wang, P., Anderko, A., & Young, R. D. (2002). A speciation-based model for mixed-solvent electrolyte systems. Fluid Phase Equilibria, 203, 141-176.
• Wang, P., Anderko, A., Springer, R. D., Kosinski, J. J., & Lencka, M. M. (2010). Modeling chemical and phase equilibria in geochemical systems using a speciation-based model. Journal of Geochemical Exploration, 106, 219-225.
• Wang, P., Anderko, A., & Young, R. D. (2004). Modeling viscosity of concentrated and mixed-solvent electrolyte systems. Fluid Phase Equilibria, 226, 71-82.
• Wang, P., Kosinski, J. J., Anderko, A., Springer, R. D., Lencka, M. M., & Liu, J. (2013). Ethylene Glycol and Its Mixtures with Water and Electrolytes: Thermodynamic and Transport Properties. I & EC Research, 52, 15968-15987.
• Wang, P., Kosinski, J. J., Lencka, M. M., Anderko, A., & Springer, R. D. (2013). Thermodynamic modeling of boric acid and selected metal borate systems. Pure Appl. Chem., 85(11), 2117-2144.
• Wang, Peiming, and Andrzej Anderko. “Computation of Dielectric Constants of Solvent Mixtures and Electrolyte Solutions.” Fluid Phase Equilibria, vol. 186, no. 1, Jan. 2001, pp. 103–122.
• Peiming Wang, Andrzej Ankderko, Jerzy J. Kosinski, Ronald D. Springer & Malgorzata M. Lencka. "Modeling Speciation and Solubility in Aqueous Systems Containing U(IV,VI), Np (IV, V, VI), Pu(III, IV, V,VI), Am(III), and Cm(III)" J.Solution Chem (2017) 46:521-588

OLI Papers and Presentations on Corrosion

• Corrosion rate calculation FAQ's
• Calculating Pitting Corrosion
• G. Englehardt, M. Urquidi-MacDonald, and D.D. MacDonald. "A simplified Method for Estimating Corrison Cavity Growth Rates." Corrosion Science, Vol. 38, No. 9, pp 1613-1635 (1996)

Unit Operations

• CSTR vs Plug Flow Reactors