Student Solutions Manual for Ball's Physical Chemistry, 2nd
Student Solutions Manual for Ball's Physical Chemistry, 2nd
2nd Edition
ISBN: 9798214169019
Author: David W. Ball
Publisher: Cengage Learning US
Question
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Chapter 14, Problem 14.66E
Interpretation Introduction

Interpretation:

The values of the five transitions for HCl using equation for the energy of a Morse oscillator are to be calculated.

Concept introduction:

Spectroscopy method is used to identify the structure of the molecule. It is based on the interactions between matter and electromagnetic radiations. An electronic state of energy has its own vibrational states. The energy between the electronic states is large followed by vibrational states and then rotational states. During an electronic transition, electron from ground state moves straight to the excited state keeping the internuclear distance constant.

Expert Solution & Answer
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Answer to Problem 14.66E

The values of the five transitions for HCl using equation for the energy of a Morse oscillator are 2885.61cm1, 5668.52cm1, 8341.69cm1, 10919.20cm1 and 13385.96cm1. The predicted values are very close to the experimental values.

Explanation of Solution

The energy of a Morse oscillator is calculated by the formula shown below.

E=hve(v+12)hvexe(v+12)2 …(1)

Where,

v is the vibrational quantum number.

h is the Planck’s constant.

xe is the anharmonicity constant.

ve is the harmonic vibrational frequency.

The value of ve for HCl is 2989.74cm1.

The value of xeve for HCl is 52.05cm1.

Convert 2989.74cm1 to s1.

2989.74cm1=2989.74cm1×2.9979×1010cms1=8962.94×1010s1

Convert 52.05cm1 to s1.

52.05cm1=52.05cm1×2.9979×1010cms1=156.04×1010s1

Substitute v=0 in equation (1).

E=hve(0+12)hvexe(0+12)2=12hve14hvexe …(2)

Substitute v=1 in equation (1).

E=hve(1+12)hvexe(1+12)2=32hve94hvexe …(3)

Subtract equation (2) from equation (3).

ΔE(v=0v=1)=(32hve94hvexe)(12hve14hvexe)=hve2hvexe …(4)

Substitute the value of Planck’s constant, ve and xeve in equation (4).

ΔE(v=0v=1)=(6.626×1034Js×8962.94×1010s12×6.626×1034Js×156.04×1010s1)=59388.44×1024J2067.84×1024J=5.732×1020J

The frequency of a transition in cm1 is calculated by the formula shown below.

v=ΔEhc …(5)

Substitute the value of ΔE, Planck’s constant and speed of light in equation (5).

v=5.732×1020J6.626×1034Js×2.9979×1010cms1=2885.61cm1

Substitute v=2 in equation (1).

E=hve(2+12)hvexe(2+12)2=52hve254hvexe …(6)

Subtract equation (2) from equation (6).

ΔE(v=0v=2)=(52hve254hvexe)(12hve14hvexe)=2hve6hvexe …(7)

Substitute the value of Planck’s constant, ve and xeve in equation (7).

ΔE(v=0v=2)=(2×6.626×1034Js×8962.94×1010s16×6.626×1034Js×156.04×1010s1)=118776.88×1024J6203.53×1024J=1.126×1019J

The frequency of a transition in cm1 is calculated by the formula shown below.

v=ΔEhc …(8)

Substitute the value of ΔE, Planck’s constant and speed of light in equation (8).

v=1.126×1019J6.626×1034Js×2.9979×1010cms1=5668.52cm1

Substitute v=3 in equation (1).

E=hve(3+12)hvexe(3+12)2=72hve494hvexe …(9)

Subtract equation (2) from equation (9).

ΔE(v=0v=3)=(72hve494hvexe)(12hve14hvexe)=3hve12hvexe …(10)

Substitute the value of Planck’s constant, ve and xeve in equation (10).

ΔE(v=0v=3)=(3×6.626×1034Js×8962.94×1010s112×6.626×1034Js×156.04×1010s1)=178165.32×1024J12407.05×1024J=1.657×1019J

The frequency of a transition in cm1 is calculated by the formula shown below.

v=ΔEhc …(11)

Substitute the value of ΔE, Planck’s constant and speed of light in equation (11).

v=1.657×1019J6.626×1034Js×2.9979×1010cms1=8341.69cm1

Substitute v=4 in equation (1).

E=hve(4+12)hvexe(4+12)2=92hve814hvexe …(12)

Subtract equation (2) from equation (12).

ΔE(v=0v=4)=(92hve814hvexe)(12hve14hvexe)=4hve20hvexe …(13)

Substitute the value of Planck’s constant, ve and xeve in equation (13).

ΔE(v=0v=4)=(4×6.626×1034Js×8962.94×1010s120×6.626×1034Js×156.04×1010s1)=237553.76×1024J20678.42×1024J=2.169×1019J

The frequency of a transition in cm1 is calculated by the formula shown below.

v=ΔEhc …(14)

Substitute the value of ΔE, Planck’s constant and speed of light in equation (14).

v=2.169×1019J6.626×1034Js×2.9979×1010cms1=10919.20cm1

Substitute v=5 in equation (1).

E=hve(5+12)hvexe(5+12)2=112hve1214hvexe …(15)

Subtract equation (2) from equation (15).

ΔE(v=0v=5)=(112hve1214hvexe)(12hve14hvexe)=5hve30hvexe …(16)

Substitute the value of Planck’s constant, ve and xeve in equation (16).

ΔE(v=0v=5)=(5×6.626×1034Js×8962.94×1010s130×6.626×1034Js×156.04×1010s1)=296942.20×1024J31017.63×1024J=2.659×1019J

The frequency of a transition in cm1 is calculated by the formula shown below.

v=ΔEhc …(17)

Substitute the value of ΔE, Planck’s constant and speed of light in equation (17).

v=2.659×1019J6.626×1034Js×2.9979×1010cms1=13385.96cm1

Conclusion

The values of the five transitions for HCl using equation for the energy of a Morse oscillator are 2885.61cm1, 5668.52cm1, 8341.69cm1, 10919.20cm1 and 13385.96cm1. The predicted values are very close to the experimental values.

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Chapter 14 Solutions

Student Solutions Manual for Ball's Physical Chemistry, 2nd

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