Diatomic molecules like hydrogen have energies due to both translations as well as rotational motion. From the equation in kinetic theory `pV =2/3 E,E " is "`

For a diatomic gas having 3 translational and 2 rotational degree of freedom ,the energy is given by ?

The key feature of Bohr's spectrum of hydrogen atom is the quantization of angular momentum when an electron is revolving around a proton. We will extend this to a general rotational motion to find quantized rotational energy of a diatomic molecule assuming it to be rigid.The rule to be applied is Bohr's quantization condition. it is found that the excitation from ground to the first excited state of rotation for the CO molecule is close to (4)/(pi) xx 10^(11) Hz then the moment of inertia of CO molecule about its center of mass is close to (Take h = 2 pi xx 10^(-34) J s )

The key feature of Bohr's spectrum of hydrogen atom is the quantization of angular momentum when an electron is revolving around a proton. We will extend this to a general rotational motion to find quantized rotational energy of a diatomic molecule assuming it to be rigid.The rule to be applied is Bohr's quantization condition. In a CO molecule, the distance between C (mass = 12 a. m. u ) and O (mass = 16 a.m.u) where 1 a.m.u = (5)/(3) xx 10^(-27) kg , is close to

The key feature of Bohr's spectrum of hydrogen atom is the quantization of angular momentum when an electron is revolving around a proton. We will extend this to a general rotational motion to find quantized rotational energy of a diatomic molecule assuming it to be rigid.The rule to be applied is Bohr's quantization condition. In a CO molecule, the distance between C (mass = 12 a. m. u ) and O (mass = 16 a.m.u) where 1 a.m.u = (5)/(3) xx 10^(-27) kg , is close to

At ordinary temperatures, the molecules of an ideal gas have only translational and rotational kinetic energies. At high temperatures they may also have vibrational energy. As a result of this, at higher temperature

At ordinary temperatures, the molecules of an ideal gas have only translational and rotational kinetic energies. At high temperatures they may also have vibrational energy. As a result of this, at higher temperature

Rotational energy levels of diatomic molecules are well described by the formula E_(J)=BJ(J+1) , where J is the rotational quantum number of the molecule and B its rotational constant. B is related to the reduced mass mu and the bond length R of the molecule through the equation B=h^(2)/(8pi^(2)muR^(2)) . In general, spectroscopic transitions appear at photon energies which are equal to the energy difference between appropriate states of a molecule (hv=DeltaE) . The observed rotational transitions occur between adjacent rotational levels, hence DeltaE=E_(J+1)-E_(J)=2B(J+1) . Consequently, successive rotational transitions that appear on the spectrum (such as the one shown here) follow the equation h(Deltaupsilon)=2B . By inspecting the spectrum provided, determine the following quantities for ^(2) C ^(p)C with appropriate units (a) Deltaupsilon (b) B (c) R

At ordinary temperatures, the molecules of an ideal gas have only translational and rotational kinetic energies. At high temperatures, they may also have vibrational energy. As a result of this, at higher temperatures, molar specific heat capacity at constant volume, C_(V) is

Calculate the dimensional formula of energy from the equation E= 1/2 mv^2 .

A vessel contains a mixture of 2 moles o hydrogen and 3 moles of oxygen at a constant temperature. The ratio of average translational kinetic energy per H_2 molecule to that per O_2 molecule is