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Lab. 12 - Determine the ? value of air ??12:?? ? ????

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Lab. 12 - Determine the value of air 12 I. Object: Measure the ratio of air using Clement & Desorms method. – PowerPoint PPT presentation

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Title: Lab. 12 - Determine the ? value of air ??12:?? ? ????


1
Lab. 12- Determine the ? value of air??12?? ?
????
  • I. Object Measure the ? ratio of air using
    Clement Desorms method.
  • ????????????????????
  • cp/cv ???????????,
  • -- ?????????????

2
Adiabatic process (????)
  • Broilge Law at constant T,an ideal gas with the
    fixed particles obeys PV nRT constant.
  • But real gas isnt a good heat conductor, it need
    time to reach a new thermal equilibrium.
  • As P and V change too rapidly, e.g., the
    propagation of sound, the energies between the
    parts of gas can not exchange with each other at
    once.
  • So it is impossible for the isothermal process
    (????), the realize reaction shall be an
    adiabatic process.
  • Adiabatic process
  • If gas is compressed (expanded), all work done by
    the surrounding becomes (dissipate) the internal
    energy of gas, thus the P and T of gas will
    simultaneously increase (decrease).
  • The slope of p(V) curve in adiabatic process must
    steeper than in the isothermal process.

3
Principle (??)
  • ???????(????)???? U ??? dU
  • (1st thermodynamical law energy conservation
    law)
  • ?/?????(endothermic/exothermic reaction do
    positive work) dU dQ dW
  • ?/?????(endothermic/exothermic reaction do
    negative work) dU dQ pdV
  • ??????(molar heat capacity at constant volume)
  • ?????? (molar heat capacity at constant
    pressure)
  • ?????(T 300 K)????????? (Air at 300 K can be
    as idea gas)
  • pV NkT , pV nRT
  • N ??? (Particle number)
  • k 1.38 x 10-23 J/K ?????(Boltzman
    constant)
  • n ? N/NA ?????(Molar no.)
  • NA 6.02 x 1023 /mol
    ??????(Advogadro constant)
  • R ? kNA 8.31 J/mol-K ???? (Gas
    constant)

4
Derive the ? value of idea gas
Ideal gases pV nRT ? pdV Vdp
nRdT Constant Pressure dp 0 (???) dQ dU
pdV dU nRdT
  • cP cv R
  • ? cp/cv (cV R)/cv
  • ????(Equipartition of Energy) kT/2 per degree of
    freedom
  • ??????????N2 78, O2 21,???(T 300 K)
  • ? ?3???????,2???????,??????
  • ? ???????5???,?????? kT/2 ???
  • ? ???Total U 5nRT/2
  • ???? cv 5 R/ 2 ???? cp cv
    R 7 R/ 2
  • ??????????? ? ? cp/cV 7/5

5
Internal Energy of an ideal Gas ???????
(19 11)
6
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7
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8
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9
  • Cv 3/2R 12.5 J/mol.K
  • Cp 5/2R 20.8 J/mol.K
  • Theoretical values of CV, CP, and ? are in
    excellent agreement for monatomic gases.

10
Molar Specific Heat for an Ideal gas
  • Several processes can change the temperature of
    an ideal gas.
  • Since DT is the same for each process, DEint is
    also the same.
  • The heat is different for the different paths.
  • The heat associated with a particular change in
    temperature is not unique.
  • Specific heats are frequently defined at two
    processes
  • Constant-pressure specific heats cp
  • Constant-volume specific heats cv
  • Using the number of moles, n, defines molar
    specific heats for these processes.

11
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12
Adiabatic expansion dQ 0 (????)
For an ideal gas with n 1
  • Here both A and A are constant values.
  • The slope of p(V) curve in adiabatic process must
    steeper than in the isothermal process.
  • One can determine the ? value from the adiabatic
    process.

13
(19 16)
14
Block Diagram of Clement-Desorms Experiment
1
2
3
P1 T1 To V1
P2 Po T2 V2
P3 T3 To V3 V2
(1)
(2) P1V1 P3V2
(1) Adiabatic expansion (2) Isothermal expansion
15
Clement-Desorms Configuration???-???????
  1. ?????(spherical glassware)
  2. ??(Cupper Tip, ??????????????????)
  3. ??? (rubber tube)
  4. ???? (glass valve)
  5. ??? (gas charging ball)
  6. U-???(U-shape soft tube, ??????????)

16
Clement-Desorms Experiment Configuration ???-????
??????
Initial condition of system at room
temperature, T0 300 K and under ambient
atmosphere, p0 1 atm (?????????,???????????)
(1) ?A????,?B????? ??????????????????,
????????p1, ??????? ????, ?????????,
?U?????????????h1, ?? p1 p0
h1dg d ???????, g ????? T1
T0
17
  • (2) ?B?, ???????????, ?????????, ?B?.
  • p2 p0
  • p1V1? p2V2? (????, ?????????)
  • T2 lt T1 T0 (???????)
  • (3) ????, ????????????
  • T3 T0 (???)
  • ???????h3,? p3 p0 h3dg
  • (A) p1V1 n1RT0 (T1 T0)
  • (n1/n3)p3V3 (T0 T3)
  • p3V3
    (n1 n3)
  • (B) p1V1? p0V2? (p2 p0)
  • p0V3?
    (V2 V3, ?????????)
  • (A)?/(B) p1?-1 p3?/p0 (p1,
    p3??)
  • or ? h3/(h1 - h3) (???? ?
    7/5 1.4 ??)

18
? Value derived in Classical Mechanics
19
Molar Specific Heat
  • Specific heats are frequently defined at two
    processes
  • Constant-pressure specific heats cp
  • Constant-volume specific heats cv
  • Using the number of moles, n, defines molar
    specific heats for these processes.
  • Molar specific heats
  • Q nCvDT for constant volume processes
  • Q nCpDT for constant pressure processes
  • Q (in a constant pressure process) must account
    for both the increase in internal energy and the
    transfer of energy out of the system by work.
  • Q(constant P) gt Q(constant V) for given values of
    n and DT

20
Ideal Monatomic Gas- contains only one atom per
molecule
  • When energy is added to a monatomic gas in a
    container with a fixed volume, all of the energy
    goes into increasing the translational kinetic
    energy and temperature of gas.
  • There is no other way to store energy in such a
    gas.
  • Eint 3/2nRT, in general, the internal energy of
    an ideal gas is a function of T only.
  • The exact relationship depends on the type of gas
  • At constant volume, Q DEint nCvDT, applies to
    all ideal gases, not just monatomic ones.

21
Specific Heat of Monatomic Gases
  • At constant volume, Q DEint nCvDT
  • applies to all ideal gases, not just monatomic
    ones.
  • Cv 3/2R 12.5 J/mol.K
  • Be in good agreement with experimental results
    for monatomic gases.
  • In a constant pressure process, DEint Q W
  • Cp Cv R ? Cp 5/2R 20.8 J/mol.K
  • This also applies to any ideal gas
  • Define a Ratio of Molar Specific Heats
  • Theoretical values of CV, CP, and ? are in
    excellent agreement for monatomic gases or any
    ideal gas.

22
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23
Adiabatic Process for an Ideal Gas
  • At any time during the process, PV nRT is valid
  • None of the variables alone are constant
  • Combinations of the variables may be constant
  • The pressure and volume of an ideal gas at any
    time during an adiabatic process are related by
    PVg constant
  • All three variables in the ideal gas law (P, V,
    T) can change during an adiabatic process

24
  • ??
  • ??????

Adiabatic compression process
25
Equipartition of Energyfor Complex Molecules
  • Other contributions to internal energy must be
    taken into account
  • Translational motion of the center of mass 3
    degrees of freedom
  • Rotational motion about the various axes 2
    degrees of freedom for x and z axes
  • ? To neglect the rotation around the y axis since
    it is negligible compared to the x and z axes.
  • Eint 5/2nRT
  • CV 5/2R 20.8 J/mol.K
  • Cp 7/2R 29.1 J/mol.K
  • predicts that g 7/5 1.40

26
Equipartition of Energy
  • The molecule can also vibrate
  • There is kinetic energy and potential energy
    associated with the vibrations
  • This adds two more degrees of freedom
  • Eint 7/2nRT, Cv 7/2R 29.1 J/mol.K
  • g 1.29
  • This doesnt agree well with experimental
    results.
  • A wide range of temperature needs to be included.
  • For molecules with more than two atoms, the
    vibrations are more complex. ? The number of
    degrees of freedom is larger
  • The more degrees of freedom available to a
    molecule, the more ways there are to store
    energy, and the higher molar specific heat.

27
Agreement with Experiment-Molar specific heat of
a diatomic gas (acts like a monatomic gas) is a
function of T.
at high T CV 7/2R
at about room T Cv 5/2R
at low T Cv 3/2R
28
Quantization of Energy
  • Classical mechanics is not sufficient to explain
    the results of the various molar specific heats,
    we must use some quantum mechanics.
  • The rotational and vibrational energies of a
    molecule are quantized

The energy level diagram of the rotational and
vibrational states of a diatomic molecule.
  • The vibrational states are separated by larger
    energy gaps than are rotational states.
  • 1. At low T, the energy gained during collisions
    is generally not enough to raise it to the first
    excited state of either rotation or vibration.
  • Even though rotation and vibration are
    classically allowed, they do not occur.

29
DVD ??????(Engine of Nature)(MU46)
??????? ?????? dU dQ dW (??????? ????
????(work)) dU TdS pdV (S ?dQ/T
??(entropy)) ??(???)(heat engine) ??(Tinput)??
Qi, Si Qi/Ti (Ti constant) ??(Toutput)?? Qo,
So Qo/To ???? W Qi Q0 ??(efficiency) e ?
W/Qi 1 Qo/Qi ????(Carnot cycle)/????(Carnot
engine) 1.??????(isothermal expansion) Ti
constant, ??Qi 2.????(adiabatic expansion) dQ 0
(??), Ti ? To (??) 3.??????(isothermal
compression), To constant, ??Q0 4.????(adiabatio
c compressiion) dQ 0, To ? Ti (??) ? W/Qi
1 To/Ti (Si So, ????/ideal heat engine)
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