PES 2130 Fall 2014, Spendier Lecture 4/Page 1

PES 2130 Fall 2014, Spendier
Lecture 4/Page 1
Lecture today: Chapter 19
1) One example on work done by gas
2) Kinetic Theory (Kinetic-Molecular Model)
Announcements:
- HW 1 due, HW 2 given out
Last lecture:
Pressure (p)= “average” force (F) per area (A): p=F/A
unit: N/m2 = Pa (Pascal)
Avogadro's number: 1 mole = 6.022 x 1023.
1 mole = number of atoms in a 12 g sample of carbon-12 (6 protons and 6 neutrons)
The Ideal Gas Law:
pV = NkBT
N = number of molecules
kB = 1.38 × 10−23 J/K = Boltzmann’s constant
If forced to use moles: n = number of moles: N = n × NA
pV = nRT
R= kB × NA = 8.31 J/mole · K = gas constant
Work done by gas (area underneath p-V diagram)
Vf
Wgas 
 pdV > 0 (expansion)
Vi
Vf
Wgas 
 pdV
< 0 (compression)
Vi
Terms:
- isothermal process
==> constant T (changing p & V)
- isobaric process
==> constant p
- isovolumetric or isochoric ==> constant V
W = nRTln(Vf/Vi)
W = p(Vf-Vi)
W=0
PES 2130 Fall 2014, Spendier
Lecture 4/Page 2
Why is a p-V diagram useful?
Below is an example for a p-V diagram. Every cycle the area underneath the path from D
via A to B is larger than the area under the path back to D from B via C. So for each
cycle there is more work done by the gas than is done one the gas. Therefore energy is
produced that is equal to the shaded region of the diagram. Hence, the study of
thermodynamics is important for the study of engines.
Example 1:
Air is expanded isothermally from a pressure of 2.00 atm to a pressure of 1.20 atm. It's
original volume was 0.139 m3. Then the gas is cooled at constant pressure until it reaches
its' original volume. Compute the work done by the air.
PES 2130 Fall 2014, Spendier
Lecture 4/Page 3
Kinetic Theory
The kinetic Theory was developed after the Ideal Gas Law. It tries to make connections
between macroscopic variables like p, V and T and the microscopic mechanisms
underlying them. The
The assumptions of the kinetic-molecular model are:
1) A container contains a very large number of identical molecules.
2) The molecules behave like point particles that are small compared to the size of the
container and the average distance between molecules.
3) The molecules are in constant motion and undergo perfectly elastic collisions.
4) The container walls are perfectly rigid and do not move.
Pressure from Collisions
Let’s try to determine the pressure (p=F/A) on the walls of a container from the collisions
of the molecules.
Fist we need to find force:
dP
Remember that F 
…. P = momentum of particle
dt
PES 2130 Fall 2014, Spendier
Lecture 4/Page 4
Assumption: All molecules of the gas have the same magnitude of velocity in the
direction towards the wall, half toward, and half away.
A molecule with mass m is in a box of length
L and hits one wall and bounces back. The
momentum change for this collision(xcoordinate) is:
Px   Px , f    Px ,i 
Px   mvx    mvx   2mvx
After bouncing off one wall it will hit the
opposing wall and come back to the initial
wall. The round trip time between 2 walls is:
t 
2L
vx
We can now calculate the rate of momentum transfer from this one molecule to the initial
wall:
dP
F
dt
P
2mvx
mvx 2

Fx= x 
t
2 L / vx
L
So the total pressure p=F/A on the wall due to all N molecules is:
∑
(
)
Now it is convenient to define an average velocity as
v 
2
x
av

1 2
 vx1  vx22  vx23  ......  vxN2 
N
to write
mN
mN 2
p  3  vx 2  
 vx av
av
L
V
Now, because each direction can be treated basically the same (since the velocities are
high, gravity doesn’t matter)
PES 2130 Fall 2014, Spendier
v   v   v   v 
v   v   v 
2
2
av
2
y
av
v 
2
av
2
y
av
2
x
x
2
x
av
Lecture 4/Page 5
z
av
2
av
z
av
1
  v2 
av
3
So that the pressure can be related to the average molecular speed:
p
mN 2
1 mN 2
2 N 1

vx  
v  
m  v2  



av
av
av
V
3 V
3 V 2

average translational kinetic energy:  KEtr av 
1
m  v2 
av
2
Hence
pV 
2
N  KEtr av
3
Molecular Kinetic Energy and Temperature
But, if we compare this result to the ideal gas law taken from experiment, then:
2
N  KEtr av  nRT
3
3 n
RT
 KEtr av 
2N
pV 
So the temperature times the number of moles is related to the total kinetic energy of the
substance, or:
 KEtr av 
3 n
3 N
RT 
RT
2N
2 NN A
 KEtr av 
3 R
3
T  kBT
2 NA
2
The average kinetic energy is directly related to the temperature (kB is the Boltzmann
constant), as we supposed to get. Or the velocity of a molecule depends only on the
temperature of the gas and the mass of the molecule.
PES 2130 Fall 2014, Spendier
Lecture 4/Page 6
Equipartition of Energy
It turns out that one of the fundamental principles of physics is the “Equipartition of
Energy”.
It states that in thermal equilibrium, energy is shared equally among all of its various
forms; Every kind of molecule has a certain number of degrees of freedom, which are
independent ways in which the molecule can store energy.
Equipartition Theorem: Every "degree of freedom" that a microscopic object has is
1
1
associated with energy of kB T per molecule (or RT per mole).
2
2
We know that a molecule can have translational, rotational, and vibrational (oscillatory)
motion. Each of these motions will add a degree of freedom.
Since we know that a monatomic gas has 3 translational degrees of freedom, the average
1
kinetic energy must equal to 3 times kB T :
2
3
monatomic gas:  KEtr av  kBT (example He)
2
The total internal energy for N molecules for a monatomic ideal gas (gas that has
individual atoms rather than molecules) is
3
N monatomic ideal gas molecules: Eint  NkBT
2
Note: Internal energy of a diatomic gas (3 translational d.o.f. plus 2 rotational d.o.f. = 5
d.o.f)
diatomic gas molecule:
Root-mean-square speed, vrms:
The square root of (v2)avg is a kind of average speed, called the root-mean-square speed of
the molecules and symbolized by vrms. Its name describes it rather well: You square each
speed, you find the mean (that is, the average) of all these squared speeds, and then you
take the square root of that mean.
 KEtr av 
3 R
T
2 NA
1
3 R
m  v2  
T
avg
2
2 NA
v 
2
avg

3RT
mN A
PES 2130 Fall 2014, Spendier
vrms 
v 
2
avg

Lecture 4/Page 7
3RT
mN A
molar mass of the gas: M  mN A
vrms 
3RT
M
This tells us how the temperature of the gas (a purely macroscopic quantity) depends on
the speed of the molecules (a purely microscopic quantity). By using the ideal gas law
you can also show how volume and pressure (macroscopic quantity) depend on the speed
of the molecules (microscopic quantity).