The equilibrium separation of H atoms in the H2 molecule is 0.074 nm.
A) Calculate the energy of photons for the rotational transition ℓ=3 to ℓ=2.
B) Calculate the wavelength of photons for the
rotational transition ℓ=3 to ℓ=2.
The equilibrium separation of H atoms in the H2 molecule is 0.074 nm. A) Calculate the...
8. The cesium iodide (CsI) molecule has an atomic separation of
0.127 nm. (a) Determine the energy of the second excited rotational
state, with J 5 2. (b) Find the frequency of the photon absorbed in
the J 5 1 to J 5 2 transition.
8. The cesium iodide (CsI) molecule has an atomic sepa ration of 0.127 nm. (a) Determine the energy of the second excited rotational state, with J 2. (b) Find the frequency of the photon absorbed...
The atoms of an LiCl molecule are separated by a distance r = 0.200 nm. (a) Calculate the reduced mass of an LiCl molecule. kg (b) Calculate the moment of inertia of an LiCl molecule. kg · m2 (c) Calculate the wavelength of radiation emitted when an LiCl molecule undergoes a transition from the J = 2 state to the J = 1 state. cm
4. The H2 molecule absorbs UV radiation of wavelength 109 nm. What is the origin of this absorption, i.e. what transition does this absorption correspond to and what eneray (in kJ mol-1) is involved? Why does absorbing ultraviolet radiation of this wavelength cause H2 to sp respective atoms? lit into its
Calculate the wavelength (in nm) of the red line in the visible
spectrum of excited H atoms using Bohr Theory.
(Question #2)
QUESTIONS 1. Determine the energy change (in Joules) associated with the transition from n = 2 to n 4 in the Hydrogen atom. AE 2.18 x 10 J nf - tests AE2.1io o.as-o.o6d5) x IDJ -/4 2. Calculate the wavelength (in nm) of the red line in the visible spectrum of excited H atoms using Bohr Theory.
SOLVE THE 3RD ONE INCLUDE ALL
THE STEPS
At a given temperature the rotational states of molecules are distributed according to the Boltzmann distribution. Of the hydrogen molecules in the ground state estimate the ratio of the number in the ground rotational state to the number in the first excited rotational state at 300 K. Take the interatomic distance as 1.06 Å. Estimate the wavelength of radiation emitted from adjacent vibration energy levels of NO molecule. Assume the force constant...
Solve 1st one asap
At a given temperature the rotational states of molecules are distributed according to the Boltzmann distribution. Of the hydrogen molecules in the ground state estimate the ratio of the number in the ground rotational state to the number in the first excited rotational state at 300 K. Take the interatomic distance as 1.06 Å. Estimate the wavelength of radiation emitted from adjacent vibration energy levels of NO molecule. Assume the force constant k-1,550 N m In...
We can construct a classical model for the hydrogen molecule H2 similar to Rutherford's model of a hydrogen atom. It resembles the Lewis dot structure H:H, as shown in the figure. The bond length of H2 is 0.074 nrm (a) What separation of the electrons is required for the net force on a proton to vanish? (b) There is no net force on either proton in this arrange- ment, but there is a net force on each electron. Calculate the...
The separation between the oxygen and carbon atoms in a carbon molecule is 0.113 nm. Assume the charges are +1.0e and -1.0e. a) Find the electric dipole moment of the CO molecule. b) We immerse the molecule into a uniform electric field of strength 2.0 x 105 N/C and oriented such that the electric dipole moment is making an angle of 53 degrees with respect to the field. What is the net torque in the molecule around its center of...
By using photons of specific wavelengths, chemists can dissociate gaseous HI to produce H atoms with certain speeds. When HI dissociates, the H atoms move away rapidly, whereas the heavier I atoms move more slowly. Given that the bond energy of H-I is 300.4 kJ/mol, what is the longest wavelength (in nm) that can dissociate a molecule of HI?
By using photons of specific wavelengths, chemists can dissociate gaseous HI to produce H atoms with certain speeds. When HI dissociates, the H atoms move away rapidly, whereas the heavier I atoms move more slowly. Given that the bond energy of H-I is 286.1 kJ/mol, what is the longest wavelength (in nm) that can dissociate a molecule of HI?