1. Calculate the translational energy difference, in cm-1, between the 1,1,2 and the 1,1,3 energy levels of a 1-H 79-Br molecule confined to a cube with sides of 0.50 nm. The isotopic masses of H and 79Br are 1.008 and 78.918 g mol-1, respectively.

2. Calculate the vibrational energy difference, in cm-1, for the v=4 and v=3 states of 1-H 79-Br. The isotopic masses of H and 79-Br are 1.008 and 78.918 g mol-1, respectively. The HBr force constant is 410 N m-1.

3. Calculate the rotational energy difference in cm-1 between the l =5 and l =4 levels of a 1-H 79-Br molecule. The isotopic masses of H and 79-Br are 1.008 and 78.918 g mol-1, respectively. The HBr bond length is 0.141 nm.

4. Calculate the electronic energy difference in cm-1 between the n=3 and n=1 levels of a hydrogen atom.

The spacing between successive vibrational energy levels is h omega = h v, where v is the vibrational frequency, v = omega/(2 pi). Vibrational frequencies are commonly reported as wavenumbers, v/c, in units of cm^-1.^1H^35CI absorbs at 2991 cm^-1. The vibrational frequencies are ordered as follows:^14n_2 >^16O_2>^1H^19F>^1H^35CI The vibrational frequencies of the isotopologues of HCI are ordered as follows:^1H^35CI >^1H^37CI >^2H^35CI >^2H^37CI Vibrational transitions of N2 and 02 are dipole forbidden, and consequently very weak. The following table lists the force constants for some diatomic molecules, and the masses of the associated isotopes: Diatomic molecule kl (N m^-1)

Prove that when including the centrifugal distortion constant, for a transition from the lowr (f'') to the upper (f') rotational state. delta Eret = 2Bhj' - 4Dh2j-3 The first three absorption lines in the rotational spectrum for HBr arc at 16.93,33.86, and 50.78 cm~x. Ignoring the (liny) centrifugal distortion term of the above equation, calculate the rotational constant. B. (in Hz) and bond length of HBr (in pm) from these data and from the rediKcd mass of the molcculc (don't forget to convert the reduced maw to kg/moleculc before plugging it into the moment of inertia equation). Prove that when including the anharmonicity coefficient, for a transition from the lower (v") to the upper (v') vibrational state. Delta Evib = [1 - 2xe(v')]hv Ignoring the (minute) anharmonicity effects, the fundamental vibrational frequency for HBr U 2648 cm-1, and the fundamental vibration frequency for DBr is 1879 cm-1 (where "D" is a dcuteron, 2 H). Calculate the force constants (in N/m) for HBr and DBr (remember, reduced masses are should be in kg/molecule) - See Example 17.2 in the textbook for guidance.