The moment of inertial of 12 C-16 O is I = 1.454 × 10°46 kg*m². The molecule also has a force constant for the C-O bondof 1920N*m. Take the atomic masses of 12 C to be 12.00aμ and 160 to be 16.00aµμ and the conversion factor from16atomic mass unit to kg to be 1, 66054 x 1027 kμ. a) Calculate the bond length for the 12 C-1 O molecule b) Calculateathe reduced mass for the 12 C-16 O molecule c) Calculate the vibrational frequency of 12 C-160 d) Calculate the zeropoint vibrational energy of this molecule e) Calculate the moment of inertia for the molecule f) Calculate the rotationalenergy of the J = 1 and J = 2 energy levels

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-46 The moment of inertial of 12 C-160 is I = 1.454 × 100 kg*m. The molecule also has a force constant for the C-O bond of 1920N*m Take the atomic masses of 12 C to be 12.00aμ and 160 to be 16.00aμ and the conversion factor from -1 atomic mass unit to kg to be 1,66054x1027 kμ. a) Calculate the bond length for the 12 C-160 molecule b) Calculate a the reduced mass for the 12 C-160 molecule c) Calculate the vibrational frequency of 12 C-160 d) Calculate the zero point vibrational energy of this molecule e) Calculate the moment of inertia for the molecule f) Calculate the rotational energy of the J = 1 and J = 2 energy levels

-46 The moment of inertial of 12 C-160 is I = 1.454 × 100 kgm. The molecule also has a force constant for the C-O bond of 1920Nm Take the atomic masses of 12 C to be 12.00aμ and 160 to be 16.00aμ and the conversion factor from -1 atomic mass unit to kg to be 1,66054x1027 kμ. a) Calculate the bond length for the 12 C-160 molecule b) Calculate a the reduced mass for the 12 C-160 molecule c) Calculate the vibrational frequency of 12 C-160 d) Calculate the zero point vibrational energy of this molecule e) Calculate the moment of inertia for the molecule f) Calculate the rotational energy of the J = 1 and J = 2 energy levels

Chemistry

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ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

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Chapter1: Chemical Foundations

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Question

The moment of inertial of 12 C-16 O is I = 1.454 × 10°46 kg*m². The molecule also has a force constant for the C-O bond
of 1920N*m. Take the atomic masses of 12 C to be 12.00aμ and 160 to be 16.00aµμ and the conversion factor from
16
atomic mass unit to kg to be 1, 66054 x 1027 kμ. a) Calculate the bond length for the 12 C-1 O molecule b) Calculate
a
the reduced mass for the 12 C-16 O molecule c) Calculate the vibrational frequency of 12 C-160 d) Calculate the zero
point vibrational energy of this molecule e) Calculate the moment of inertia for the molecule f) Calculate the rotational
energy of the J = 1 and J = 2 energy levels

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