The potential energy vs bond distance of a diatomic molecule AB is given, if a= 6225x10-20 J, and the classical frequency of vibration is 2553.18 cm³¹, what is the experimental dissociation energy (in J)? Potential energy at. VO a. 5.1e-20 b. 7.6e-20 c. 2.5e-20 d. 6.2e-17 e. 1.0e-19 distance A+B
The potential energy vs bond distance of a diatomic molecule AB is given, if a= 6225x10-20 J, and the classical frequency of vibration is 2553.18 cm³¹, what is the experimental dissociation energy (in J)? Potential energy at. VO a. 5.1e-20 b. 7.6e-20 c. 2.5e-20 d. 6.2e-17 e. 1.0e-19 distance A+B
Physical Chemistry
2nd Edition
ISBN:9781133958437
Author:Ball, David W. (david Warren), BAER, Tomas
Publisher:Ball, David W. (david Warren), BAER, Tomas
Chapter15: Introduction To Electronic Spectroscopy And Structure
Section: Chapter Questions
Problem 15.69E
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Question
![The potential energy vs bond distance of a diatomic
molecule AB is given, if a= 6225x10-20 J, and the
classical frequency of vibration is 2553.18 cm³¹,
what is the experimental dissociation energy (in J)?
Potential energy
at.
VO
a. 5.1e-20
b. 7.6e-20
c. 2.5e-20
d. 6.2e-17
e. 1.0e-19
distance
A+B](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fa8eae833-8f0b-44a4-8c0e-f9208c87f4e9%2Fdf74ad7b-db58-43c8-8f13-6b94d23983ff%2Fd88vqyg_processed.jpeg&w=3840&q=75)
Transcribed Image Text:The potential energy vs bond distance of a diatomic
molecule AB is given, if a= 6225x10-20 J, and the
classical frequency of vibration is 2553.18 cm³¹,
what is the experimental dissociation energy (in J)?
Potential energy
at.
VO
a. 5.1e-20
b. 7.6e-20
c. 2.5e-20
d. 6.2e-17
e. 1.0e-19
distance
A+B
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