Transcript Slide 1
Lecture #8
Cassandra Paul
Physics 7A
Summer Session II 2008
Announcements
• No Lecture or DL on Monday! (Labor Day)
• There is DL on Tuesday and Wednesday.
• I will be out of town next Tuesday and Wednesday.
– Substitute for my office hours.
• Lecture next Wednesday
– Sub
– Evaluations
– Short Lecture
– Quiz 5
• Review Sessions posted over the Weekend
• Final Lecture Monday September 8th
Today
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Intro Model to Thermodynamics
Ideal Gas Model
Practice with both
Enthalpy
Microstates
Entropy
Intro Model of Thermodynamics
A tool we use to talk about the
internal energy of a system.
What is Thermodynamics?
In a nutshell, it is the
study of
the transfer of energy
between systems and
how the energy instills
movement, i.e., how the
system responds.
Ex. If we heat something,
it expands.
Open box of gas
But wait… does it have to expand?
No, we can constrain the system.
Closed box of gas
Open box of gas
Does it take more or less energy to change the
temperature of the constant volume system?
Closed box of gas
A) More
B) Less
C) The Same
D) Depends on
Substance
Open box of gas
Does it take more or less energy to change the
temperature of the constant volume system?
Closed box of gas
Open box of gas
CV
measurement
CP
measurement
Closed box:
all heat goes into the gas’s
internal energy
Open box:
Some heat goes into
pushing air out of the way
(work is leaving the
system)
What is ‘work’ in the
Thermodynamic Model?
Final
Work
Eth
T
ΔEth = W
Volume is decreasing, positive work is being done on the system.
Initial
What is ‘work’ in the
Thermodynamic Model?
Work
T
Eth
ΔEth = W
Initial
Volume is increasing, negative work is being done by the system.
Final
U = Internal Energy
When we add heat or work to a substance we
are changing the internal energy, but what is
internal energy anyway?
It is the energy of the system associated with
the particles in the system.
ΔEth + ΔEbond = ΔU = Q + W
Eth + Ebond = U
Then how is U different than Etot?
It does not include external energies of the
system. For example…
If we throw a coconut off the
roof…
The Internal Energy of the coconut:
• Does not account for the height
of the coconut
• Does not account for the velocity
of the coconut
• Does account for the
Temperature of the coconut
• Does account for the bond
energy of the coconut
• Does account for the average KE
of the particles in the coconut
• Does account for the average PE
of the particles in the coconut
ΔU is a part of ΔEtot
∆Etotal must include all changes of energy associated with the
system…
∆Etotal = ∆Ethermal + ∆Ebond + ∆Eatomic + ∆Enuclear + ∆Emechanical
∆U : Internal energy
Energy associated with the atoms/molecules inside
the body Of material
Energy associated with
the motion of a body
as a whole (KE and PE of total
System)
Remember
conservation of energy?
…if there’s no change in ∆Emechanical,
∆U
First law of Thermodynamics
External Energies vs. U
External
Internal (U)
• KE of the SYSTEM
• PE of the SYSTEM
• Average KE of the
Particles in the system
• Average PE of the
Particles in the system
• Eth of the System
• Ebond of the System
State Functions
A State Function is a macroscopic property of a
physical system of matter that has a definite
value that depends only on certain observable
parameters of a system.
A State Function does not depend on how the
system evolved, but only on the value of the
current parameters. (Initial and Final values)
Let’s bring back a bucket of water…
What are some observable (measurable)
properties of the water in this bucket?
Temperature
Pressure
Volume
Eth
PE
All State Functions!!!!!!
Eb
KE
Entropy
Enthalpy
But can I measure how much heat was
added and work was done on this
bucket since the beginning of time?
Only If you were there since the beginning of time!
State Functions can have
an Instantaneous Value,
Processes can not!
Processes
• Processes are quantities that depend on HOW a
system ends up at it’s final state.
• The have no ‘instantaneous values.’ They can only be
measured over some period of time.
• They are not considered properties of the system.
Can you think of any processes? (Hint: they cause
change, but aren’t changes themselves.)
Heat and Work!
ΔU = Q + W
This is the “First Law of Thermodynamics”
It is often EXTREMELY useful to use it like this:
ΔEth + ΔEbond = ΔU = Q + W
And to also use it in conjunction with the Ideal
gas law, so let’s pause a moment and
(officially) introduce the ideal gas model…
Ideal Gas Model
A tool we use to describe gases in
situations where we can ignore interparticle interactions.
PV=nRT or PV=NkBT
• n= number of moles
• N=number of atoms
• kB =1.381x10-23 J/K
• R=8.314 J/(K mole)
There are other constructs of this model, but
most we have introduced in other places,
check the blue pages for more information.
OK what I was saying…
• It is VERY useful to use the first law of
thermodynamics with the sum of the internal
energies and with ideal gas law:
ΔU = Q + W
ΔU =ΔEth + ΔEbond
PV=nRT
Let’s See How…
Here is a particular cycle that happens to
one mole of a monatomic gas, no phase
change happens during this process.
x105
b
a
c
x10-3
Let’s write this on the board so we can keep track of it.
From abca, what is ΔU?
Let’s see:
ΔU =ΔEth + ΔEbond
ΔU =ΔEth
ΔU = (# of modes per particle)(# of particles) ½ kBΔT
ΔU = 3(6.02x1023) ½ kB(Tf-Ti)
OK… let’s find the T at a and a…. wait…
The final STATE is the same so:
Tf=Ti! Therefore ΔU = 0
Note: if you don’t believe me, use PV=nRT
OK well what is the Q for the
process abca ?
ΔEth + ΔEbond = ΔU = Q + W
Does Q equal zero for this process? (Don’t
calculate anything.)
A.Yes, Q = 0
B.No, Q has a negative value
C.No, Q has a positive value
D.Can’t be determined.
What is the Q for the process
abca ?
ΔEth + ΔEbond = ΔU = Q + W
ΔU = Q + W = 0
Work is easier to find, let’s find that and then
get our Q.
Work for abc:
Wabc= ½ (1x10-3 x 1x105) + (1x10-3 x 1x105)
x105
Positive of Negative?
b
Negative W: V is increasing
a
c
Wabc = -150J
x10-3
Work for ca:
Wca = (1x10-3 x 1x105)
Positive of Negative?
Positive W: V is decreasing.
Wca = 100J
Wabca = Wabc + Wca = -150J + 100J = -50J
What is the Q for the process
abca ?
ΔEth + ΔEbond = ΔU = Q + W
ΔU = Q + W = 0 = Q + -50J
Q = 50J
Harder Problem…
What is the change in Eth from bc?
Start with:
ΔEth + ΔEbond = ΔU = Q + W
ΔEth = Q + W
We could find W… but how do we find Q?
Need to use something else…
PV=nRT!
Harder Problem…
What is the change in Eth from bc?
ΔEth = Q + W
PbVb=nRTb
(2x105)(1.8x10-3) = (1)(8.31)Tb
Tb = 43.3°K
PcVc=nRTc
(1x105)(2.3x10-3) = (1)(8.31)Tc
Tc = 27.7°K
What is the change in Eth from
bc?
ΔEth = Q + W
Tb = 43.3°K
Tc = 27.7°K
What equation do we use for Eth?
ΔEth = (# of modes per particle)(# of particles) ½ kBΔT
ΔEth = (3)(6.02x1023) ½ (1.38x10-23) (27.7 – 43.3)
ΔEth = -194.4 J
So… use all three equations
together!
ΔU = Q + W
ΔU =ΔEth + ΔEbond
PV=nRT
Enthalpy
Is a state function:
- U depends only on state of system
- P depends only on state of system
- V depends only on state of system
=> H depends only on state of system
(Hess’s law)
Enthalpy
Constant volume
P
Constant pressure
P
final
initial
final
initial
V
V
W=0
*Derivation in P.84
ΔEth + ΔEbond = ΔU = Q + W
Note: works for solids and liquids too!
Intro to Statistical Model of
Thermodynamics
A tool we use discuss probability of
particles or a system being in a
certain state.
States and Microstates
• A state in the Thermodynamic Model is a
combination of instantaneously measurable
parameters.
– Ex: Solid phase, 30C, at 1Atmosphere of Pressure.
• You can think of it is any point on any state
diagram
P
4
2
1
3
5
V
What the heck is a Microstate?
• A microstate is one of the different ‘ways’ a
system can be in that state.
State 1
P
Microstate1
V
What the heck is a Microstate?
• A microstate is one of the different ‘ways’ a
system can be in that state.
State 1
P
Microstate 2
V
What the heck is a Microstate?
• A microstate is one of the different ‘ways’ a
system can be in that state.
State 1
P
Microstate 3
V
Let’s try a real world example..
(Well sort 0f real world)
After graduating from Davis, you
decide you love it here so much
that you want to start a farm and
live here forever..
You go to the state Fair to get your first animals.
There are only two kinds for sale and you can
only buy 1.
You go back the next day, and pick another one.
What are your possible combinations?
What are the States? And what are
the microstates of the system?
State = 1Cow and 1 Sheep
Microstate = CS
State = 2 Cows
Microstate = CC
State = 1Cow and 1Sheep
Microstate = SC
State = 2 Sheep
Microstate = SS
Three States, but 4 microstates, which State is most probable?
If you leave it up to chance…
You are most likely to have a state of one cow
and one sheep, because there are more
microstates in that state!