CHEM 1040 Chapter 18
For a perfect crystal at absolute 0, the absolute entropy is
0 J/ mol x K
The standard enthalpy of formation, delta H f, of an element is
0 Kj/mol
For solids and liquids, the standard state corresponds to the pure solid or liquid in the most stable form at exactly
1 atm pressure and temperature of interest, most of the time at 25 degrees C
The first law of thermodynamics states that
energy cannot be created or destroyed
A nonreversible transformation can be reversed by using
energy to drive the back, nonspontaneous process
The enthalpy change is favorable for
exothermic and unfavorable for endothermic
When the entropy change in a system is unfavorable (negative), the entropy change in the surroundings must be
favorable (positive) and large in order to allow the process to be spontaneous
Entropy is a thermodynamic state function that
growths all the number of energetically equivalent ways of arranging the component increases
Enthalpy change (delta H)
heat involved in a process occurring at constant p
When a process of the system is exothermic
heat is released to surroundings Increase S much more in surroundings than the decrease of system
If the entropy of the system decreases during a spontaneous process, the entropy of the surroundings must
increase by a larger amount
Evaporation of H2O
increase in entropy
Salt dissolving in water
increase in entropy
Above 0 degrees C, the increase in entropy of the surroundings is
insufficient to make delta S positive
The entropy change in the surroundings is also
inversely proportional to the temperature
When a system process is endothermic
it takes heat from surroundings Decreasing surroundings entropy
enthalpy change units
kJ/mol
High entropy means
large dispersal of matter/energy
Bigger more complex molecules usually have
larger entropies They possess more energy states, allowing more dispersal of energy through the states.
-Addition of heat to surroundings at low temperatures has a
larger impact on the entropy than in the case of hot surroundings
The fact that the layers in graphite are not bonded makes graphite
less constrained
Solids have fewer macrostates than
liquids which have fewer macrostates than gases
Solids more ordered than
liquids; liquids more ordered than gases
Random systems are characterized by
lower and dispersed amounts of energy as compared with that of ordered systems
The more ways molecules can move (degrees of freedom), the more
macrostates are possible
When the stopcock is open, the gas atoms distribute themselves in
many energetically equivalent ways
Different motions, degrees of freedom, are possible for
molecules and the number of possibilities increase with molecular complexity
For materials with larger molar masses, the available energy states are
more closely spaced Allows for more dispersal of energy through the states
Processes that result in a randomness increase are
more likely
Changes that increase the entropy are transformations whose products are in a
more random state
If a process is spontaneous in one direction it is
nonspontaneous in other direction
Reversible processes
occur back and forth between two conditions Most involve equilibrium situations. Net result is no change in energy
absolute entropy
of a substance is related to dispersal of energy possessed through all the particles of the material
The PE is the same, whether the molecules are all in
one flask or evenly distributed
Energy can be transferred from
one place to another
The amount of entropy of the surroundings changes depends on
original temperature
Reaction is generally endothermic (+ delta H) if the bonds in the products are
weaker than the bonds in the reactants requiring energy to be absorbed
Entropies are for 1 mol of a substance at 298 K for a particular state, a
particular allotrope, a particular molecular complexity, a particular molar mass, and a particular degree of dissolution
The absolute entropy at 25 degrees C is always
positive
When delta Ssys is negative, delta Ssurr must be
positive and big for a spontaneous process to occur.
Thermodynamics
predicts whether a process will occur under the given conditions
nonspontaneous
processes that need some input to proceed
Spontaneous
processes that occur without intervention
Entropy changes in the surroundings are
proportional to the amount of heat gained or lost
For gases the standard state corresponds to the
pure gas at exactly 1 atm pressure
Liquids exhibit larger entropies than
solids at any particular temperature
Every substance that is not a perfect crystal at absolute 0 has
some energy dispersed
Spontaneity not related to the
speed or the process (not fast or slow)
Energy is not the only considerable aspect because some endothermic processes are
spontaneous
Transport of thermal energy from a hot to colder place is
spontaneous with delta S > 0
Processes like condensation of water vapor are
spontaneous, even though water vapor is more random than liquid water.
-Standard entropy change
difference in absolute values between the reactants and products under standard conditions
The state with the highest entropy also has the greatest
dispersal of energy
macrostate
defined by variables T, p, V and n of the system, and encompasses all the possible arrangements (or microstates) that result in a specific enthalpy and entropy of the system
Delta E univ = 0 =
delta Esys + delta Esurr
Np =
# mol for each product
Nr =
# mol for each reactant
Delta s o rxn =
(sum of np S o products) - (sum of nr S o reactants)
Randomness increases when delta S is
+
The absolute entropy of substances is always
+
Qsurr =
- q sys
At constant pressure and temperature, the overall relationship is
delta S surr = -qsys/temp (T) = (-) delta H sys/ T
K is the Boltzmann constant =
1.38 x 10 ^ -23 J/K
The clustered flasks only have 1 possible arrangement while the spread-out flasks have
6
For a reversible process, delta Suniv
= 0
For irreversible (spontaneous), delta Suniv
>0
For a process in which the final condition is more random than the initial condition
delta S sys is positive The entropy change is favorable for the process to be spontaneous
Delta Suniv =
delta Ssys + delta Ssurr
For a process in which the final condition is more orderly than the initial condition
Delta S sys is negative. Entropy change is unfavorable for the process to be spontaneous
Delta S sys = delta S rxn =
En (S o products) - En (s o reactants)
2 factors that determine whether a reaction is spontaneous or not are
Enthalpy changes of system. Entropy changes of system.
Molar entropy =
J/ (mol x K)
Delta S measured in
J/k
Delta S > 0 for
Reactions that have larger numbers of product molecules than the reactant molecules Processes leading to increases in temperature. Solids dissociating into ions upon dissolving.
S solid <
S liquid < S gas
Entropy evaluated using Boltzmann equation
S= k ln W
Delta S =
Sfinal - S initial
Delta H measures the
difference between the sum of the internal energy and pV work energy of the products and reactants
Heat released by the system increase
T and the entropy of surroundings
W
a distribution, or number of energetically equivalent ways a system can exist
If a process is spontaneous, yet entropy change is unfavorable, there must have been
a large increase in surrounding entropy
The standard state of a solution consists of the substance dissolved in
a liquid with a concentration of 1 M
Low entropy means
a more ordered system
Some spontaneous processes can proceed from
a state of lower PE to another of higher PE Endothermic
The universe consists of
a system plus surroundings
Energy can be distributed among
all the possible DOF
H2O condensation is
an exothermic process
Entropy is
an extensive physical property of matter
Energy needed to
bring order to the system
Thermodynamics (kinetics)
centered on properties determined under equilibrium
When materials change their physical state, the number of macrostates they have can
change
The spread-out flask has a higher entropy than the
clustered flasks
A way to attempt assessment of spontaneity is by
comparison of the potential energy of the system before the reaction with the energy of the system after the reaction
Total universe energy remains
constant
kinetics
deals with the speed of transformations
S o designates
standard state conditions
Standard state
state of a material at a defined set of conditions, dependent on the form of material
Reaction is generally exothermic (- delta H) if bonds in the products are
stronger than the bonds in the reactants, resulting in energy release
Entropy change (delta S)
the difference between the dispersion of energy (or matter) of the products and that of the reactants
The less constrained the structure of an allotrope is, the larger
the entropy
Water freezes spontaneously below 0 degrees Celsius because
the heat released in this physical change increases the entropy of the surroundings enough to yield a positive delta S
The higher number of possible motions
the higher the entropy
Microstate
the instantaneous arrangement of energy (or position) of the components in a system
The larger the molar mass
the larger the entropy
The higher the original temperature
the less effect addition or removal of heat has
Gases exhibit larger entropies than
the liquid at any particular temperature
Entropy provides a measure of
the state of dispersal of either matter or energy in a system
The second law of thermodynamics
the total entropy change of the universe must be positive for a process to be spontaneous
Second law demands that
the universe entropy increase for spontaneous process
Spontaneous processes are irreversible because
there is a net release of energy when they proceed in a specific direction
If after the reaction the system has less PE than before, the process is
thermodynamically favorable.
Spontaneous processes may occur because
they release energy from the system Most proceed from a state of high PE to another at lower PE. This is exothermic.
