A diatomic molecules is made of two masses m_(2) and m_(2) which are separated by a distance r. We calculate its rotational energy by applying Bohr's rule of angular momentum quantization, its energy will be given by (n is an integer)

A diatomic molecules is made of two masses m_(2) and m_(2) which are s

1.	A diatomic molecules is made of two masses m_(2) and m_(2) which are separated by a distance r. We calculate its rotational energy by applying Bohr's rule of angular momentum quantization, its energy will be given by (n is an integer)
Answer» `((m_(1)+m_(2))^(2)n^(2)h^(2))/(2m_(1)^(2) m_(2)^(2) r^(2))` `(n^(2)h^(2))/(2(m_(1)+m_(2))r^(2))` `(2n^(2)h^(2))/((m_(1)+m_(2))r^(2))` `((m_(1)+m_(2))n^(2)h^(2))/(2m_(1)m_(2)r^(2))` SOLUTION : `m_(1)r_(1)=m_(2)r_(2)` `r_(1)+r_(2)=r` `r_(1)=(m_(2)r)/(m_(1)+m_(2)), r_(2)=(m_(1)r)/(m_(1)+m_(2))` `epsi=1/2 I omega^(2)` `=1/2 (m_(1)r_(1)^(2)+m_(2)r_(2)^(2))omega^(2) ........(i)` `mvr=(nh)/(2pi)=I omega` `RARR omega=(nh)/(2pi I)` `epsi=1/2 I. (n^(2)h^(2))/(4PI^(2)I^(2))` `=(n^(2)h^(2))/(8pi^(2)) (1)/((m_(1)r_(1)^(2)+m_(2)r_(2)^(2)))` `=(n^(2)h^(2))/(8pi^(2)) (1)/(m_(1)(m_(2)^(2)r^(2))/((m_(!)+m_(2))^(2))+m_(2) (m_(1)^(2)r^(2))/((m_(1)+m_(2))^(@)))` `=(n^(2)h^(2))/(8pi^(2)r^(2)) ((m_(1)+m_(2))^(2))/(m_(1)m_(2)(m_(1)+m_(2)))=((m_(1)+m_(2))n^(2)h^(2))/(8pir^(2)m_(1)m_(2))` `=((m_(1)+m_(2))n^(2)h^(2))/(2m_(1)m_(2)r^(2))`

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A diatomic molecules is made of two masses m_(2) and m_(2) which are separated by a distance r. We calculate its rotational energy by applying Bohr's rule of angular momentum quantization, its energy will be given by (n is an integer)

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