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Lecture 26Purdue University, Physics 2201 Lecture 26 Thermodynamics I PHYSICS 220.

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Presentation on theme: "Lecture 26Purdue University, Physics 2201 Lecture 26 Thermodynamics I PHYSICS 220."— Presentation transcript:

1 Lecture 26Purdue University, Physics 2201 Lecture 26 Thermodynamics I PHYSICS 220

2 Lecture 26Purdue University, Physics 2202

3 Lecture 26Purdue University, Physics 2203 First Law of Thermodynamics  U = Q - W Heat flow into system Increase in internal energy of system Work done by system Equivalent ways of writing 1st Law: Q =  U + W The change in internal energy of a system (  U) is equal to the heat flow into the system (Q) minus the work done by the system (W) Energy Conservation

4 Lecture 26Purdue University, Physics 2204

5 Lecture 26Purdue University, Physics 2205 Signs Example You are heating some soup in a pan on the stove. To keep it from burning, you also stir the soup. Apply the 1 st law of thermodynamics to the soup. What is the sign of A) Q B) W C)  U Positive, heat flows into soup Negative, stirring does work on soup Positive, soup gets warmer

6 Lecture 26Purdue University, Physics 2206 W = P  V W > 0 if  V > 0 expanding system does positive work W < 0 if  V < 0 contracting system does negative work W = 0 if  V = 0 system with constant volume does no work Work Done by a System M M yy W = F d cos  = P A d = P A  y = P  V

7 Lecture 26Purdue University, Physics 2207 PV Diagram Ideal gas law: PV = nRT For n fixed, P and V determine “state” of system T = PV/nR U = (3/2)nRT = (3/2)PV Examples: – which point has highest T? B – which point has lowest U? C – to change the system from C to B, energy must be added to system V P A B C V 1 V 2 P1P3P1P3

8 Lecture 26Purdue University, Physics 2208 V P 1 2 V 1 V 2 P 2 moles of monatomic ideal gas is taken from state 1 to state 2 at constant pressure p=1000 Pa, where V 1 = 2m 3 and V 2 = 3m 3. Find T 1, T 2,  U, W, Q. 1. pV 1 = nRT 1  T 1 = pV 1 /nR = 120K 2. pV 2 = nRT 2  T 2 = pV 2 /nR = 180K 3.  U = (3/2) nR  T = 1500 J  U = (3/2)  pV = (3/2) (3000-2000)J =1500 J (has to be the same) 4. W = p  V = 1000 J 5. Q =  U + W = 1500 + 1000 = 2500 J Example (Isobaric)

9 Lecture 26Purdue University, Physics 2209 Example (Isochoric) 2 moles of monatomic ideal gas is taken from state 1 to state 2 at constant volume V=2m 3, where T 1 = 120K and T 2 = 180K. Find Q. 1. pV 1 = nRT 1  p 1 = nRT 1 /V = 1000 Pa 2. pV 2 = nRT 2  p 2 = nRT 2 /V = 1500 Pa 3.  U = (3/2) nR  T = 1500 J 4. W = p  V = 0 J 5. Q =  U + W = 0 + 1500 = 1500 J Requires less heat to raise T at const. volume than at const. pressure C V =C P -R V P 2 1 V P2P1P2P1

10 Lecture 26Purdue University, Physics 22010 Question Shown in the picture below are the pressure versus volume graphs for two thermal processes, in each case moving a system from state A to state B along the straight line shown. In which case is the work done by the system the biggest? A) Case 1 B) Case 2 C) Same A B 4 2 39 V(m 3 ) Case 1 A B 4 2 39 V(m 3 ) P(atm) Case 2 P(atm) Net Work = area under P-V curve Area the same in both cases !

11 Lecture 26Purdue University, Physics 22011 Question Shown in the picture below are the pressure versus volume graphs for two thermal processes, in each case moving a system from state A to state B along the straight line shown. In which case is the change in internal energy of the system the biggest? A) Case 1 B) Case 2 C) Same A B 4 2 39 V(m 3 ) Case 1 A B 4 2 39 V(m 3 ) P(atm) Case 2 P(atm)  U = 3/2  (PV) Case 1:  (PV) = 4x9-2x3=30 atm*m 3 Case 2:  (PV) = 2x9-4x3= 6 atm*m 3

12 Lecture 26Purdue University, Physics 22012 iClicker Shown in the picture below are the pressure versus volume graphs for two thermal processes, in each case moving a system from state A to state B along the straight line shown. In which case is the heat added to the system the biggest? A) Case 1 B) Case 2 C) Same A B 4 2 39 V(m 3 ) Case 1 A B 4 2 39 V(m 3 ) P(atm) Case 2 P(atm) Q =  U + W W is same for both  U is larger for Case 1 Therefore, Q is larger for Case 1

13 Lecture 26Purdue University, Physics 22013 Q =  U + W Heat flow into system Increase in internal energy of system Which part of cycle has largest change in internal energy,  U ? 2  3 (since U = 3/2 PV) l Which part of cycle involves the least work W ? 3  1 (since W = P  V) l What is change in internal energy for full cycle?  U = 0 for closed cycle (since both P & V are back where they started) l What is net heat into system for full cycle (positive or negative)?  U = 0  Q = W = area of triangle (>0) Some questions: First Law Questions Work done by system V P 1 2 3 V 1 V 2 P1P3P1P3

14 Lecture 26Purdue University, Physics 22014 Special PV Cases Constant Pressure –isobaric Constant Volume –isochoric Constant Temp  U = 0 –isothermic Adiabatic Q=0 (no heat is transferred) V P W = P  V (>0) 1 2 3 4  V > 0V P W = P  V = 0 1 2 3 4  V = 0

15 Lecture 26Purdue University, Physics 22015 1st Law Summary 1st Law of Thermodynamics: Energy Conservation Q =  U + W Heat flow into system Increase in internal energy of system Work done by system V P l Point on P-V plot completely specifies state of system (PV = nRT) l Work done is area under curve l U depends only on T (U = 3nRT/2 = 3PV/2) For a complete cycle  U=0  Q=W

16 Lecture 26Purdue University, Physics 22016 Reversible? Most “physics” processes are reversible, you could play movie backwards and still looks fine. (drop ball vs throw ball up) Exceptions: –Non-conservative forces (friction) –Heat Flow Heat never flows spontaneously from a colder body to a hotter body.

17 Lecture 26Purdue University, Physics 22017 Summary of Concepts First Law of thermodynamics: Energy Conservation –Q =  U + W Heat Engines –Efficiency = 1-Q C /Q H Refrigerators –Coefficient of Performance = Q C /(Q H – Q C )

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