Announcements 2/2/11 Exam review session (tentative): Friday, 3-4:30 pm a. a.I will send email tomorrow with final date/time, and room location. (Vote.

Announcements 2/2/11 Exam review session (tentative): Friday, 3-4:30

pma. I will send email tomorrow with final date/time,

and room location. (Vote today if you haven’t yet!)

Reading assignment for Friday: a. Section 22.8 – Especially the marble example

(Ex. 22.7, in my edition), but not the “Adiabatic Free Expansion: One Last Time” example (Ex. 22.8, in my edition).

b. The “What is entropy?” handout posted to website – Read up through Example 1. Please spend at least ~10 minutes glancing over it, or you will likely be really confused in class on Friday.

Reading quiz Which of the following is a version of the

Second Law of Thermodynamics?a. The entropy of any system decreases

in all real processesb. The entropy of any system increases in

all real processesc. The entropy of the Universe decreases

in all real processesd. The entropy of the Universe increases

in all real processes

Time for some physics humor Xkcd comic:

Thermodynamics song:a. http://www.uky.edu/~holler/CHE107/media/first_second_la

w.mp3

Second Law Clausius: Heat spontaneously flows from

hot to cold, not the other way around Why? Order. Which hand is more likely?

Microstates vs Macrostates

Hand on lefta. microstate = A spades, K spd, Q spd, J spd, 10 spdb. macrostate = ?c. How many microstates make up that macrostate?

Hand on righta. microstate = 2 spades, 3 diam, 7 heart, 8 clubs, Q

diamb. macrostate = ?c. How many microstates make up that macrostate?

The most common macrostates are those that…

Probability Heat flow You separate a deck into two halves: one

is 70% red, 30% black; the other is 30% red, 70% black. What will happen if you randomly exchange cards between the two?

Thermodynamics For the air in this room, right now:

a. Microstate = ?b. Macrostate = ?

Hold this thought until Friday

A New State Variable State variables we know: P, V, T, Eint

Observation: doesn’t depend on path

Something is a state variable! Assumption: path is well defined, T exists whole time

“Internally reversible”

AB

P

V

B

A

dQ

T

“Proof” by example, monatomic gas Path 1: ACB Path 2: ADB

(DB = isothermal)

ln ln 2

ln ln 2

ln ln 4

ln1ln 2

C CV

V C A V

A A

B BP

P B C P

C C

D DP

P D A P

A A

B BB Don

D D

nC dTdQnC T T nC

T T

nC dTdQnC T T nC

T T

nC dTdQnC T T nC

T T

nRT V VworkdQ QdQ nR

T T T T T

A

BP

V

C

D

V1 2V1 4V1

P1

2P1

Path 1: AC + CB

Path 2: AD + DB

Equal?

Entropy: S

Assume S = 0 is defined somewhere.(That’s actually the Third Law, not mentioned in your textbook.)

Integral only defined for internally reversible paths, but…

S is a state variable!…so it doesn’t matter what path you use to calculate it!

B

AB

A

dQS

T

Advertisement: On Friday I’ll (try to) explain how/why this quantity is related to microstates & macrostates

S for “free expansion”

What is V2? T2? P2? How to find S?

S for adiabatic?

Adiabats as constant entropy contours (“isentropic” changes)

Wait… isn’t “free expansion” an adiabatic process?

before after

S for isothermal?

S for const. volume?

S for const. pressure?

S of Universe S of gas doesn’t depend on path (state

variable):

What about S of surroundings? What about Stotal = Sgas + Ssurroundings?

AB

P

V

path1 path 2

B

AB

A

dQS

T

S S

(See HW problem 12-4)