Molar energy

Gibbs free energy or Gibbs molar free energy molar flow of gas phase acceleration of gravity enthalpy, molar enthalpy, weight enthalpy Henry s constant Planck s constant height horsepower radiation intensity molar flux... [Pg.494]

Temperature, Heat capacity. Pressure, Dielectric constant. Density, Boiling point. Viscosity, Concentration, Refractive index. Enthalpy, Entropy, Gibbs free energy. Molar enthalpy. Chemical potential. Molality, Volume, Mass, Specific heat. No. of moles. Free energy per mole. [Pg.34]

U = molar internal energy = molar volume T = absolute temperature.) This small expansion does not necessarily disrupt all the intermolecnlar solvent-solvent interactions. [Pg.65]

For very rough estimation, one can consider the cohesive energy/ molar mass ratio as... [Pg.303]

Molar free energy Molar free energy of A... [Pg.68]

The physical property monitors of ASPEN provide very complete flexibility in computing physical properties. Quite often a user may need to compute a property in one area of a process with high accuracy, which is expensive in computer time, and then compromise the accuracy in another area, in order to save computer time. In ASPEN, the user can do this by specifying the method or "property route", as it is called. The property route is the detailed specification of how to calculate one of the ten major properties for a given vapor, liquid, or solid phase of a pure component or mixture. Properties that can be calculated are enthalpy, entropy, free energy, molar volume, equilibrium ratio, fugacity coefficient, viscosity, thermal conductivity, diffusion coefficient, and thermal conductivity. [Pg.302]

Ej,Ej( 30) ZR Molar transition energy Molar transition energy... [Pg.21]

Hard-sphere diameter Dielectric permittivity Chemical potential of substance A Energy difference, adiabatic interaction energy Dissociation energy counterpoise corrected, adiabatic interaction energy counterpoise corrected Dissociation energy, adiabatic interaction energy Solvation free energies Molar enthalpy of vaporization Dipole moment Tetrafluoroborate 1-Alkyl-3-alkyl imidazolium l-Alkyl-3-methyl imidazolium Dicyanamide... [Pg.214]

Molecule Permanent Dipole Moment (D) Permanent Dipole-Dipole Energy Dispersion Energy Total Energy Molar Heat of Vaporization (kJ/mol)... [Pg.492]

Hydration energy (molar) of an ion The energy change accompanying the hydration of a mole of gaseous ions. [Pg.583]

Certain physical properties of materials, such as the cohesive energy, molar volume, molecular weight per repeat unit, molar heat capacity, molar enthalpy and molar entropy, are extensive properties. An extensive property depends upon the size of the system. Its value increases in direct proportion to the amount of material present. For example, the molar volume... [Pg.84]

Lowercase roman letters usually denote molar properties of a phase. Thus, g, A. s, and v are the molar Gibbs energy, molar enthalpy, molar entropy, and molar volume. Whan it is essentia] to distinguish between a molar property of a mixture nod that of a pure component, we identify the pure-component property by a subscript. For example, ft, is the molar enthalpy of pure i. Total properties are usually designated by capilal letters, Thus H is the total enthalpy of a mixture it is related to the molar mixture enihelpy A by H nh. where n is the total number of moles in the mixture. [Pg.4]

Internal energy Molar volume of sorbate Volume of sorbate per unit mass of sorbent Specific micropore volume of sorbent Mole fraction in adsorbed phase Mole fraction in vapor phase Distance coordinate... [Pg.3]

Wavenumber v Frequency v Energy E Energy E Energy E Molar energy Molar energy Temperature... [Pg.50]

Fraction of water molecules with i H-bonds Gibbs energy, molar (kJ moP )... [Pg.227]

A molar Helmoltz free energy, molar Helmholtz... [Pg.617]

G molar Gibbs free energy molar Gibbs energy. [Pg.617]

The preparation of PLS nanocomposites is strongly dependent on the nature of the polymer matrix such as its surface energy, molar mass, the presence of reactive groups, characteristics of the layered silicates, and the chemical nature of the intercalants. Three main routes were reported to combine layered silicates with a polymer matrix (Fig. 24.2). [Pg.508]

Where V is the average molar volume of the beads (or molecules) A and B. The solubility parameters are material specific numbers and can be obtained from experiment or simulations. If experimental data are not available, one can, for example, perform atomistic MD simulations to calculate the cohesive energy density (CED) from the non-bonded energy (molar enthalpy of vaporization) and the molar volume. The solubility parameters can then be obtained by the following equation suggested by Hildebrand... [Pg.125]

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