Bundle: Physics for Scientists and Engineers with Modern Physics, Loose-leaf Version, 9th + WebAssign Printed Access Card, Multi-Term
Bundle: Physics for Scientists and Engineers with Modern Physics, Loose-leaf Version, 9th + WebAssign Printed Access Card, Multi-Term
9th Edition
ISBN: 9781305932302
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 43, Problem 63CP

(a)

To determine

The vibrational frequency of 14CO.

(a)

Expert Solution
Check Mark

Answer to Problem 63CP

The vibrational frequency of 14CO is 6.15×1013Hz.

Explanation of Solution

Write the expression for the reduced mass of 12CO.

  μ12=mC12mOmC12+mO                                                                                                         (I)

Here, μ12 is the reduced mass of 12CO, mC12 is the mass of 12C and mO is the mass of the oxygen atom.

Write the expression for the reduced mass of 14CO.

  μ14=mC14mOmC14+mO                                                                                                        (II)

Here, μ14 is the reduced mass of 14CO, mC14 is the mass of 14C and mO is the mass of the oxygen atom.

Write the expression for the vibrational frequency of 12CO molecule.

  f12=12πkμ12                                                                                                         (III)

Here, f12 is the vibrational frequency of 14CO molecule, and k is the spring constant of the vibrating molecule.

Both 14CO and 14CO molecules have same interatomic potential, their spring constant is same.

Write the expression for the vibrational frequency of 14CO molecule.

  f14=12πkμ14                                                                                                       (IV)

Here, f14 is the vibrational frequency of 14CO molecule.

Multiply and divide inside the square root of above equation by μ12.

  f14=12πkμ14(μ12μ12)=12πkμ12(μ12μ14)

Use equation (II) in above equation to get an expression for f12.

  f14=12πkμ14(μ12μ12)=f12(μ12μ14)                                                                                               (V)

Conclusion:

In example 43.2 it is given that frequency of photon that causes the v=0 to v=1 transition in the molecule is 6.42×1013Hz.

Substitute 12u for mC12 and 16u for mO in equation (I) to get μ12.

  μ12=(12u)(16u)(12u)+(16u)'=6.86u

Substitute 14u for mC12 and 16u for mO in equation (I) to get μ12.

  μ14=(14u)(16u)(14u)+(16u)=7.47u

Substitute 6.42×1013Hz for f12, 6.86u for μ12 and 7.47u for μ14 in equation (V) to get f14.

  f14=(6.42×1013Hz)(6.86u7.47u)=6.15×1013Hz

Therefore, the vibrational frequency of 14CO is 6.15×1013Hz.

(b)

To determine

The moment of inertia of 14CO.

(b)

Expert Solution
Check Mark

Answer to Problem 63CP

The moment of inertia of 14CO is 1.59×1046kgm2.

Explanation of Solution

Write the expression for the moment of inertia of 12CO.

  I12=μ12r2                                                                                                              (VI)

Here, I12 is the moment of inertia of the 12CO molecule, and r is the atomic separation.

Write the expression for the moment of inertia of 14CO.

  I14=μ14r2                                                                                                              (VII)

Here, I14 is the moment of inertia of the 14CO molecule.

Multiply and divide the right hand side of above equation by μ12.

  I14=(μ14μ12)μ12r2                                                                                                  (VIII)

Use equation (VI) in equation (VIII) to get I14.

  I14=(μ14μ12)I12                                                                                                        (IX)

Conclusion:

The moment of inertia of 12CO is 1.46×1046kgm2.

Substitute 1.46×1046kgm2 for I12, 6.86u for μ12 and 7.47u for μ14 in equation (IX) to get I14.

  I14=(7.47u6.86u)(1.46×1046kgm2)=1.56×1046kgm2

Therefore, the moment of inertia of 14CO is 1.59×1046kgm2.

(c)

To determine

The wavelength of light that can be absorbed by 14CO in the (=(v=0,J=10) state that cause it end up in the v=1 state.

(c)

Expert Solution
Check Mark

Answer to Problem 63CP

The wavelengths of light that can be absorbed by 14CO in the (=(v=0,J=10) state that cause it end up in the v=1 state are 4.96μm and 4.78μm.

Explanation of Solution

The molecule lies in (v=0,J=10) state. Selection rules allows only ΔJ=±1. The possible to way to end up in the v=1 state is to move into (v=1,J=11) or (v=1,J=11) state.

Write the expression for the total energy of the 14CO molecule.

  Eν,J=(v+12)hf14+22I14J(J+1)

Here, Eν,J is the energy of the molecule in particular vibrational and rotational state, ν is the vibrational quantum number and J is the rotational quantum number.

Write energy of the molecule in (v=0,J=10).

  E0,10=(0+12)hf14+22I1410(10+1)                                                                        (X)

Here, E0,10 is the energy of the molecule in (v=0,J=10).

Write energy of the molecule in (v=1,J=9).

  E1,9=(1+12)hf14+22I149(9+1)                                                                            (XI)

Here, E1,9 is the energy of the molecule in (v=1,J=9).

Write energy of the molecule in (v=1,J=11).

  E1,11=(1+12)hf14+22I1411(11+1)                                                                       (XII)

Here, E1,11 is the energy of the molecule in (v=1,J=11).

Write the expression for the change in energy during transition from (v=0,J=10) to (v=1,J=9).

  ΔE1=E1,9E0,10                                                                                                  (XIII)

Here, ΔE1 is the change in energy during transition from (v=0,J=10) to (v=1,J=9).

Write the expression for the change in energy during transition from (v=0,J=10) to (v=1,J=11).

  ΔE2=E1,11E0,10                                                                                                (XIV)

Here, ΔE2 is the change in energy during transition from (v=0,J=10) to (v=1,J=11).

Write the expression for the energy of wavelength absorbed during a transition.

  ΔE=hcλ                                                                                                                (XV)

Use equation (X) and (XI) in equation (XIII) to get ΔE1.

  ΔE1=E0,10E1,9

Conclusion:

Use equation (X) and (XI) in equation (XIII) to get ΔE2.

  ΔE1=[(1+12)hf14+22I149(9+1)][(0+12)hf14+22I1410(10+1)]=hf142022I14

Substitute hcλ for ΔE1 in above equation to get wavelength emitted.

  hcλ=hf142022I14cλ=f14102π22πhI14λ=cf14102πI14

Substitute 3×108m/s for c, 6.15×1013Hz for f14, 1.055×1034Js for and 1.59×1046kgm2 for I14 in above equation to get wavelength emitted during the transition from (v=0,J=10) to (v=1,J=9).

  λ=3×108m/s6.15×1013Hz10(1.055×1034Js)2π(1.59×1046kgm2)=4.96×106m×1μm106m=4.96μm

Use equation (X) and (XII) in equation (XIV) to get ΔE2.

  ΔE2=[(1+12)hf14+22I1411(11+1)][(0+12)hf14+22I1410(10+1)]=hf14+2222I14

Substitute hcλ for ΔE2 in above equation to get wavelength emitted.

  hcλ=hf14+2222I14cλ=f14+112π22πhI14λ=cf14+112πI14

Substitute 3×108m/s for c, 6.15×1013Hz for f14, 1.055×1034Js for and 1.59×1046kgm2 for I14 in above equation to get wavelength emitted during the transition from (v=0,J=10) to (v=1,J=11).

λ=3×108m/s6.15×1013Hz+11(1.055×1034Js)2π(1.59×1046kgm2)=4.78×106m×1μm106m=4.78μm

Therefore, the wavelengths of light that can be absorbed by 14CO in the (=(v=0,J=10) state that cause it end up in the v=1 state are 4.96μm and 4.78μm.

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