| Home » Chemistry Homework Help » Physical Chemistry » Solvent Dielectric Effect |
Solvent Dielectric Effect
Ionic dissociation depends on the dielectric constant of the solvent.
The Arrhenius that ions are in aqueous solutions in equilibrium with parent molecular species allows many of the properties of ionic solutions to be understood. But difficulties began to arise after the initial acceptance of this ionic solution is to be understood. Ultimately the Arrhenius theory was attacked for the postulating molecules instead of ions in solutions of strong electrolytes. This was a dramatic reversal of the initial attacks on the Arrhenius theory which criticized it for postulating ions instead of undissolved molecules.
Refinements to the simplest ideas of the ionic solutions depend on the recognition of the role of the solvent and on the effect of interactions between the ions.
A remarkable feature of the Arrhenius electrolytic dissociation theory is that although it attributes the dissociation process to the solution of the electrolyte, it proceeds to ignore the role of the solvent. It treats the solvent as if it were an inert, ignorable medium. A detailed understanding of the molecular nature of ionic solutions must involve the very important role played by the solvent. It is necessary, for instance, to understand why water is a unique solvent for ionic systems.
The electrostatic force of attraction between ions of charge Z+ and Z- is given by Coulomb’s law:
For vacuum: ƒ(r) = Z+Z-[e2/4∏ε0)]/r2
For medium of dielectric ε/ε0: ƒ(r) = Z+Z-[e2/4∏ε0)]/(ε/ε0)r2
With the numerical values for e2/4∏ε0, the second of this equation is:
ƒ (r) = (2.307 × 10-28) Z+Z-/(ε/ε0)r2
For water, the dielectric constant factor ε/ε0 has the very large value of about 80. The force of interaction and the energy required to overcome coulombic forces are thus smaller by almost of very low dielectric. The easy dissociation of electrolytes in aqueous solutions compared with gaseous or low phase dielectric material is therefore understandable in terms of the high dielectric constant of water. The initial criticisms raised against the Arrhenius theory for postulating the dissociation of electrolysis in solution, however, remain valid arguments against any theory postulating appreciable dissociation to form free ions insolvents of low dielectric constant.
Although the dielectric effect is a major factor for the formation of ionic species in aqueous solutions, it is not great enough to reduce the intermolecular interaction to the small values found for gas phase molecules. We must therefore produce that for all but extremely dilute solutions, ionic interactions will not produce behavior found at infinite dilutes.
A similar treatment of the activities themselves leads, again for one to one electrolytes, to the mean activity
Extension of this property lets activities and their coefficients be defined for electrolytes beyond the AB type. An AB2 electrolyte would dissociate according to
AB2 = A2+ + 2B-
And the activity term that would appear in all thermodynamic treatments would be of form:
(aA2+) (aB-)2
Services:- Solvent Dielectric Effect Homework | Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Homework Help Services | Live Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Homework Tutors | Online Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Tutors | Online Solvent Dielectric Effect Tutors | Solvent Dielectric Effect Homework Services | Solvent Dielectric Effect
The Arrhenius that ions are in aqueous solutions in equilibrium with parent molecular species allows many of the properties of ionic solutions to be understood. But difficulties began to arise after the initial acceptance of this ionic solution is to be understood. Ultimately the Arrhenius theory was attacked for the postulating molecules instead of ions in solutions of strong electrolytes. This was a dramatic reversal of the initial attacks on the Arrhenius theory which criticized it for postulating ions instead of undissolved molecules.
Refinements to the simplest ideas of the ionic solutions depend on the recognition of the role of the solvent and on the effect of interactions between the ions.
A remarkable feature of the Arrhenius electrolytic dissociation theory is that although it attributes the dissociation process to the solution of the electrolyte, it proceeds to ignore the role of the solvent. It treats the solvent as if it were an inert, ignorable medium. A detailed understanding of the molecular nature of ionic solutions must involve the very important role played by the solvent. It is necessary, for instance, to understand why water is a unique solvent for ionic systems.
The electrostatic force of attraction between ions of charge Z+ and Z- is given by Coulomb’s law:
For vacuum: ƒ(r) = Z+Z-[e2/4∏ε0)]/r2
For medium of dielectric ε/ε0: ƒ(r) = Z+Z-[e2/4∏ε0)]/(ε/ε0)r2
With the numerical values for e2/4∏ε0, the second of this equation is:
ƒ (r) = (2.307 × 10-28) Z+Z-/(ε/ε0)r2
For water, the dielectric constant factor ε/ε0 has the very large value of about 80. The force of interaction and the energy required to overcome coulombic forces are thus smaller by almost of very low dielectric. The easy dissociation of electrolytes in aqueous solutions compared with gaseous or low phase dielectric material is therefore understandable in terms of the high dielectric constant of water. The initial criticisms raised against the Arrhenius theory for postulating the dissociation of electrolysis in solution, however, remain valid arguments against any theory postulating appreciable dissociation to form free ions insolvents of low dielectric constant.
Although the dielectric effect is a major factor for the formation of ionic species in aqueous solutions, it is not great enough to reduce the intermolecular interaction to the small values found for gas phase molecules. We must therefore produce that for all but extremely dilute solutions, ionic interactions will not produce behavior found at infinite dilutes.
A similar treatment of the activities themselves leads, again for one to one electrolytes, to the mean activity
Extension of this property lets activities and their coefficients be defined for electrolytes beyond the AB type. An AB2 electrolyte would dissociate according to
AB2 = A2+ + 2B-
And the activity term that would appear in all thermodynamic treatments would be of form:
(aA2+) (aB-)2
Services:- Solvent Dielectric Effect Homework | Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Homework Help Services | Live Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Homework Tutors | Online Solvent Dielectric Effect Homework Help | Solvent Dielectric Effect Tutors | Online Solvent Dielectric Effect Tutors | Solvent Dielectric Effect Homework Services | Solvent Dielectric Effect
Submit Your Query ???
Assignment Help
Inorganic Chemistry
Organic Chemistsry
Analytical Chemistry
Biochemistry
Physical Chemistry
Topics
Covalent Radii
Crystal Shapes, Point Groups
Diffraction Pattern Assignments
Electron Diffraction
Ionic Radii
Lattice Energies
Diffraction
Lattices, Unit Cells
Neutron Diffraction
Waals Radii
X-ray Diffraction
Bond Moments
Electric Capacitor
Atoms, Molecules Properties
Paramagnetism
Electrolytic Dissociation
Solution Ionic Strength
Solvent Dielectric Effect
Electrolysis
Solutions Ionic Mobilities
Electrolytes In Solutions
Solutions Molar Conductance
Solutions Specific Conductance
Electrochemical Cell EMF
Electrodes
Ion Selective Electrodes
Junction Potentials
Cells Electromotive Force
Standard Electrode Potentials
Collision Theory
Gas Viscosity Theory
Elementary Reactions
Lasers
Molecule-Molecule Collisions
Electrochemical Cell
Photochemical Quenching
Surface Decompositions
Atomic Molecular Energies
Molecular Energies
Particle-in-a-box
Particle-on-a-line
Rotational Energies
Schrodinger Wave Equation
De Broglie Wave Length
Vibrational Energies
Waves And Particles
Boltzmann Distribution
Gas Heat Capacities
Metals Heat Capacities
Molecules Collection Energies
One Dimensional Motion
Partition Function
Rotational Motions
Thermal Energy
Three Dimensional Motion
Vibrational Motions
Aqueous Ion Energies
Bond Energies
Chemical Systems Energy
Enthalpy, Chemical Reactions
Chemical System Enthalpy
Thermodynamics First Law
Heat Capacities
Thermodynamics
Molecular Thermal Energy
Standard Enthalpy Substance
Carnot Cycle
Absolute Zero Entropies
Entropy
Thermodynamics Laws
Entropy Molecular Basis
Third Law Molecular Basis
Rotational Energy
Thermodynamics Second Law
Thermodynamics Third Law
Vapourization Entropy
Vibrational Entropy
Equilibria And Distributions
Real Gases Equilibria
Free Energy Equilibrium Constant
Free Energy And Pressure
Free Energy, Temperature
Free Energy Function
Free Energy Real Gases
Free Energy
Fugacity
Non-ideal Gases Fugacity
Thermodynamic Properties
Chemical Equilibria
Boyle Gas Pressure
Continuity Of States
Critical Point
Gas Mixtures
Kinetic Molecular Theory
Gases-Properties, Theories
Molecular Energies, Speed
Molecular Interactions
Real Gas PVT
Temperature Volume
Waals Gases Behaviour
Waals Critical Point
Molecular Diameters
Virial Equation
Diffusion Coefficient
Diffusion Molecular View
Donnan Membrane Equilibria
Electrophoresis
Macromolecular Dynamics
Average Mass Range
Solution Viscosity
Sedimentation And Velocity
Colloids Macromolecules Micelles
Adsorption Isotherm
Adsorption Of Gases
Boiling Point Diagrams
Pressure Temperature Relation
Distillation
Eutectic Formation
Immiscible Liquids
Phase Equilibria
Liquid Surfaces
Phase Rule
Pressure Phase Diagrams
Solid Compound Foundation
Surface Tension Vapour Pressure
Three Component System
Vapour Pressure Composition
Atomic States
Bohr Atom
Electron Spin
Angular Momentum Hydrogen
Hydrogen Atom Spectra
Hydrogen Radical Factor
Quantum Atomic Structure
Quantum Mechanical Operators
Variation Theorem
Enzymes Catalyzed Reactions
First Order Rate Equations
Flash Photolysis
Chemical Reactions Mechanism
Enzyme Reactions Mechanism
Reactions Mechanisms
Photochemical Reactions
Rate Equation
Second Order Rate Equations
Temperatures And Rates
Unimolecular Gas Reactions
Absorption Coefficient
Einstein Coefficient
Electromagnetic Induction
Electronic Spectra
Electron Spin Spectroscopy
Infrared Adsorption
Spectroscopy
Microwave Absorption
Nuclear Spin States
Nuclear Magnetic Resonance
Photoelectron Spectroscopy
Polyatomic Vibrational Spectra
Rotational Vibrational Spectra
Conjugated Systems Spectra
Transition Moment
Character Tables
Symmetry Group Theory
Molecular Symmetry Types
Orbital Symmetries
Point Groups
Reducible Representation
Symmetry Elements, Operations
Molecular Properties Symmetry
Transformation Matrices
Diatomic Molecule Orbitals
Electronegativity
Hybridization
Hydrogen Molecule Ion
Ionic Bond
Molecular Orbitals
Orbitals Pie Electrons
Two Electron Bond
Virial Theorem
Partial Molal Properties
Solute Free Energy
Ideal Mixtures
Solution Thermodynamic Property
Liquid Vapour Free Energies
Osmotic Pressure
Partial Molal Quantities
Solvent Free Energy
Vapour Pressure Lowering
Homework Help, Online Tutor, Online Tutoring Available For All Subjects. Some useful topics are given below :