announcements 9/17/12 prayer sps opening social: thursday 5-7 pm answer this question while you’re...
TRANSCRIPT
Announcements 9/17/12 Prayer SPS Opening Social: Thursday 5-7 pm Answer this question while you’re waiting for class to
start: Ralph is confused because he knows that when you compress gases, they tend to heat up (think of a bicycle pump nozzle getting hotter as you force the gas from the pump to the tire). So, how are “isothermal” processes even possible? How can you compress a gas without its temperature increasing?
Calvin & Hobbes
From warmup
Extra time on?a. molar specific heat (e.g. why different depending on
what you hold constant) b. total differentialc. The book says that "This expression predicts a value of
Cv=3/2R=12.5 for all Monatomic gases", but the actual experimental Cv values are also listed on the opposing page. When working problems, should we use the predicted universal value or the experimental actual value for Cv of a Monatomic gas?
Other comments?a. Out of curiosity, how is our TA 's name spelled? Does it
have an accent like “Clément”? Cause his name is actually kind-of cool.
Clicker questions: A gas has its pressure reduced while its volume
is kept constant. What does this look like on a PV diagram?
a. a horizontal line going to the rightb. a horizontal line going to the leftc. a vertical line going upd. a vertical line going down
Same situation. How did the temperature of the gas change during that process?
a. the temperature increasedb. the temperature decreasedc. the temperature stayed the samed. the temperature change cannot be
determined from the information given
From warmup
For each process discuss whether Q, Won, and ΔEint are positive, negative, or zero.
a. Process 1-volume constant – W=0, Q=+, E=+
b. Process 2 – W=-, Q=+, E=+
Clicker question:
How will the temperature of the gas change during this process from A to B?
a. Increaseb. Decreasec. First increase, then
decreased. First decrease, then
increasee. Stay the same
Worked Problem (by class)
A diatomic ideal gas undergoes the change from A to B. How much heat was added to or taken away from the gas?
(First: was heat added or taken away?)Answer: 151500 J
Clicker question:
What is “CV”?
a. heat capacity b. molar heat capacityc. molar heat capacity, but only for
constant volume changesd. specific heat
Q = n CV T (const. volume)Q = n CP T (const. pressure)
Clicker question:
Which will be larger, the molar heat capacity for constant volume changes or the molar heat capacity for constant pressure changes? (Hint: Think of the First Law--does it take more heat to increase temperature by 1C if volume is constant or if pressure is constant?)
a. constant volumeb. constant pressurec. they are the same
CV and CP
Constant volume change (monatomic):W = 0Eint = Qadded
(3/2)nRT = Qadded
Compare to definition of C: Qadded = nCVT
CV = (3/2)R (monatomic)
Constant pressure changea. What’s different?b. result: CP = (5/2)R (monatomic)
What would be different for gases with more degrees of freedom?
From warmup
Explain why some modes (vibrational or rotational) do not contribute to the specific heat except at higher temperatures.
a. The vibrational and rotational degrees of freedom of a molecule are not initiated until the molecule is subjected to higher levels of temperature so it doesn 't effective the specific heat of a molecule until it has is at higher temperatures.
b. Not quite: “vibrational and rotational kinetic energies can only contribute to the specific heat when there is a significant amount of energy stored in them.”
Isothermal vs Adiabatic
Isothermal: Adiabatic:
What does gamma equal?
steeper curves for adiabatic
constantPV constantPV
Clicker question:
How much would the temperature of the air in this room would change if I compressed it adiabatically by a factor of 2? (V2 = 1/2 V1)
a. less than 0.2 degree Cb. about 0.2 degrees Cc. about 2 degree Cd. about 20 degrees Ce. more than 20 degrees C
From warmup
What does it mean to “take the total differential”?
a. You take the derivative of every single variable in an equation
b. Mostly correct: You take the derivative of both sides, using the product rule on the first side.
Derivation of PV (for Monatomic)
Eint = Qadded + Won
(3/2) nRT = - PdV(3/2) nRdT = -PdV(3/2) nR d(PV/nR) = -PdV(3/2) (PdV + VdP) = -PdV(3/2) VdP = -(5/2) PdVdP/P = -(5/3) dV/VlnP = (-5/3)lnV + constantlnP = ln(V-5/3) + constantP = constant V-5/3 (it’s a different
constant)P V5/3 = constant
What’s differentif diatomic?