| Home » Chemistry Homework Help » Physical Chemistry » Entropy Molecular Basis |
Entropy Molecular Basis
The equation S = k in W relates entropy to W, a measure of the number of different molecular level arrangements of the system.
In the preceding developments it was unnecessary to attempt to reach any “explanation” of entropy. But the history of chemical shows that we get great insight into, and control over, the material word then we seek and develop a molecular level interpretation of properties and phenomena. It is not immediately obvious what molecular phenomenon is responsible for the entropy of a system. Some idea of what should be calculated can be obtained by tying to discover a quantity that would tend to increase when an isolated system moves spontaneously toward the equilibrium position. A very non chemical example will reveal such a quantity.
Consider a box containing a large number of pennies. Suppose, further, that the pennies are initially arranged so that they all have heads showing. If the box is now shaken, the chances are very good that some arrangement of higher probability, with a more nearly equal number of heads and tails, will result. This system of pennies has, therefore, a natural, or spontaneous, tendency o go from the state of low probability to one of high probability. The system can be considered to be isolated since no energy is transferred, and the shaking process could almost be presented by using some other objects that could turn over more easily. The deriving that operates in this isolated system is seen to be the probability. The system tends to be change towards its equilibrium position and this change is accompanied by an increase in the probability. Such an example suggests that the entropy might be identified with some functions like probability. The next sections will show in more detail that the entropy is quantitat
vely related to the probability.
Now consider a slightly more chemical example. Consider the equilibrium of A and B in which B molecules have more available quantum states than do A molecules. There then more ways of distributing the atoms in these states so that the molecules of type B are formed then there are ways of arranging the atoms in that a molecule of type B, even if no energy driving force exists, is therefore understood to be due to the driving force that takes place the system from a state of lower probability of few quantum states and few possible arrangements, to one of higher arrangements. The qualitative result from this discussion is: a substance for which the molecules have and therefore the higher number of molecular level arrangements and therefore the higher entropy.
The molecular explanation of the entropy change in the system is basically quite simple. In practice, of course, it is not always easy to see whether a process or reaction, produces a system with more, or less, available quantum states or energy levels. For example, for the liquid to vapour transition a large entropy increase occurs. The difficult encountered in a molecular understanding of the liquid state make it very difficult to evaluate this entropy increase from the molecular model.
Entropy and the number of molecular level arrangements: the headstone on Ludwig Boltzmann’s grave has the inscription:
S = k In W
The inscription does not go on to say, “where k, now known as Boltzmann’s constant, is the gas constant per molecule-level arrangements that the particles can adopt for the specific macroscopic state.”
The relation S = k In W boldly relates S, a macroscopic property, to W, a molecular-level quantity. It is an elegant display of the chemistry. You will accept it, and appreciate it, as we use it to calculate entropies and compare the results with the values based on calorimetric relation.
The general relation for W was developed after a “marbles-in-boxes” analysis, we arrived at the relation:
W = (g1N1 g2N2 g3N3…) 1/N1! N2! N3!...
And in W = Σ Ni In gi – Σ In Ni!
With Sterling’s approximation In (x!)
In x – x, which is valid for large numbers, this expression for In W can be recast as:
In W = Σ Ni (1 + In gi/Ni)
We want an expression for In W for the Boltzmann distribution. The most convenient form of this distribution is given, for an Avogadro’s number of particles, written as:
Ni/gi = N/q e- (ε1 – ε0)/(kT)
Where q is the partition function, clearly to develop we need the logarithm of the reciprocal of this Boltzmann expression. This is:
In gi/Ni = ε1 – ε0/kT + In q/N
Services:- Entropy Molecular Basis Homework | Entropy Molecular Basis Homework Help | Entropy Molecular Basis Homework Help Services | Live Entropy Molecular Basis Homework Help | Entropy Molecular Basis Homework Tutors | Online Entropy Molecular Basis Homework Help | Entropy Molecular Basis Tutors | Online Entropy Molecular Basis Tutors | Entropy Molecular Basis Homework Services | Entropy Molecular Basis
In the preceding developments it was unnecessary to attempt to reach any “explanation” of entropy. But the history of chemical shows that we get great insight into, and control over, the material word then we seek and develop a molecular level interpretation of properties and phenomena. It is not immediately obvious what molecular phenomenon is responsible for the entropy of a system. Some idea of what should be calculated can be obtained by tying to discover a quantity that would tend to increase when an isolated system moves spontaneously toward the equilibrium position. A very non chemical example will reveal such a quantity.
Consider a box containing a large number of pennies. Suppose, further, that the pennies are initially arranged so that they all have heads showing. If the box is now shaken, the chances are very good that some arrangement of higher probability, with a more nearly equal number of heads and tails, will result. This system of pennies has, therefore, a natural, or spontaneous, tendency o go from the state of low probability to one of high probability. The system can be considered to be isolated since no energy is transferred, and the shaking process could almost be presented by using some other objects that could turn over more easily. The deriving that operates in this isolated system is seen to be the probability. The system tends to be change towards its equilibrium position and this change is accompanied by an increase in the probability. Such an example suggests that the entropy might be identified with some functions like probability. The next sections will show in more detail that the entropy is quantitat
vely related to the probability.
Now consider a slightly more chemical example. Consider the equilibrium of A and B in which B molecules have more available quantum states than do A molecules. There then more ways of distributing the atoms in these states so that the molecules of type B are formed then there are ways of arranging the atoms in that a molecule of type B, even if no energy driving force exists, is therefore understood to be due to the driving force that takes place the system from a state of lower probability of few quantum states and few possible arrangements, to one of higher arrangements. The qualitative result from this discussion is: a substance for which the molecules have and therefore the higher number of molecular level arrangements and therefore the higher entropy.
The molecular explanation of the entropy change in the system is basically quite simple. In practice, of course, it is not always easy to see whether a process or reaction, produces a system with more, or less, available quantum states or energy levels. For example, for the liquid to vapour transition a large entropy increase occurs. The difficult encountered in a molecular understanding of the liquid state make it very difficult to evaluate this entropy increase from the molecular model.
Entropy and the number of molecular level arrangements: the headstone on Ludwig Boltzmann’s grave has the inscription:
S = k In W
The inscription does not go on to say, “where k, now known as Boltzmann’s constant, is the gas constant per molecule-level arrangements that the particles can adopt for the specific macroscopic state.”
The relation S = k In W boldly relates S, a macroscopic property, to W, a molecular-level quantity. It is an elegant display of the chemistry. You will accept it, and appreciate it, as we use it to calculate entropies and compare the results with the values based on calorimetric relation.
The general relation for W was developed after a “marbles-in-boxes” analysis, we arrived at the relation:
W = (g1N1 g2N2 g3N3…) 1/N1! N2! N3!...
And in W = Σ Ni In gi – Σ In Ni!
With Sterling’s approximation In (x!)
In x – x, which is valid for large numbers, this expression for In W can be recast as:In W = Σ Ni (1 + In gi/Ni)
We want an expression for In W for the Boltzmann distribution. The most convenient form of this distribution is given, for an Avogadro’s number of particles, written as:
Ni/gi = N/q e- (ε1 – ε0)/(kT)
Where q is the partition function, clearly to develop we need the logarithm of the reciprocal of this Boltzmann expression. This is:
In gi/Ni = ε1 – ε0/kT + In q/N
Services:- Entropy Molecular Basis Homework | Entropy Molecular Basis Homework Help | Entropy Molecular Basis Homework Help Services | Live Entropy Molecular Basis Homework Help | Entropy Molecular Basis Homework Tutors | Online Entropy Molecular Basis Homework Help | Entropy Molecular Basis Tutors | Online Entropy Molecular Basis Tutors | Entropy Molecular Basis Homework Services | Entropy Molecular Basis
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 :