The first two anti-Stokes lines in the rotational Raman spectrum of N2 occur at 29709.1 and...

Calculate the rotational Raman spectrum of NH3 when it is exposed to monochromatic 336.732 nm laser...

Calculate the rotational Raman spectrum of NH3 when it is exposed to monochromatic 336.732 nm laser radiation. Label the lines as Stokes, anti-Stokes or Rayleigh. Assume 14N, 1H and the rotational constant is 9.977 cm-1. I am trying to understand this so please show all work. Thank you!

The molecule carbon tetrachloride (CCl4) has three Raman-active absorptions that occur at 218, 314 and 459...

The molecule carbon tetrachloride (CCl4) has three Raman-active absorptions that occur at 218, 314 and 459 cm-1 away from the laser line. Draw a representation of the Raman spectrum of CCl4 that includes both the Stokes and anti-Stokes lines. Draw the placement of the Stokes and anti-Stokes lines of CCl4.

3b Two of the adjacent absorption lines in the pure rotational spectrum of 23Na81Br occur at...

3b Two of the adjacent absorption lines in the pure rotational spectrum of 23Na81Br occur at 3.623 and 3.92 cm-1 . Assuming 23Na81Br behaves as a rigid rotor: i) Calculate the moment of inertia for this molecule. ii) Calculate the bond length of 23Na81Br. iii) Determine the most intense transition in the rotational spectrum of 23Na81Br if the measurement is carried out at 25oC. c The rigid rotor model assumes that the molecular bond does not stretch during rotation. Describe...

The first line (peak) in the 12CO rotational spectrum is observed at 3.84235 cm-1 (corresponds to...

The first line (peak) in the 12CO rotational spectrum is observed at 3.84235 cm-1 (corresponds to the transition J-0 -> J-1). Calculate B, the rotational constant of 12CO (in cm-1). Calculate r, the link length of 12CO (in Armstrong) Calculate the position (the wave number, in cm-1) of the peak corresponding to the transition J-0 -> J-1 of 13CO. Molar masses (g/mol): 12C-12.00, 13C-13,0006, O-15.9994.

Three discrete spectral lines occur at angles of 11.0°, 13.9°, and 14.9° in the first-order spectrum...

Three discrete spectral lines occur at angles of 11.0°, 13.9°, and 14.9° in the first-order spectrum of a grating spectrometer. (Assume that the light is incident normally on the gratings.) (a) If the grating has 3 670 slits/cm, what are the wavelengths of the light? (Enter your answers from smallest to largest.) nm   nm   nm (b) At what angles are these lines found in the second-order spectrum? (Enter your answers from smallest to largest.) ° ° °

Calculate the wavelength ranges to be scanned for CHCl3 and CCl4 for the (a) Stokes spectra...

Calculate the wavelength ranges to be scanned for CHCl3 and CCl4 for the (a) Stokes spectra and (b) anti-Stokes spectrum assuming that the wavelength of the laser is 532.2 nm and that the range of vibrational frequencies is 100-3200 cm^-1 for CHCl3 and 100-1000 cm^-1 for CCl4

The microwave spectrum of the 12C16O molecule consists of a series of lines separated by 3.913...

The microwave spectrum of the 12C16O molecule consists of a series of lines separated by 3.913 cm−1. Draw the corresponding energy level diagram for this spectral line spacing for the first 5 energy levels, assuming the rigid rotor model. Give the value for the energy gap between each level.

The microwave spectrum of 39K127I consists of a series of lines whose spacing is almost constant...

The microwave spectrum of 39K127I consists of a series of lines whose spacing is almost constant at 3634 MHz. Calculate the bond length of 39K127I.

the microwave spectrum of (39)K(127)I consists of lines spaced by 3634 MHz. what it's the bond...

the microwave spectrum of (39)K(127)I consists of lines spaced by 3634 MHz. what it's the bond length of this molecule? I know i need to find the reduced mass would i then plug that into v= 1/2pi sqrt(k/reduced mass) and solve for k? and after that not sure where to go to solve for bond length, please help

The spectrum of a light source has two lines with lB =504nm(blue) and λR = 672...

The spectrum of a light source has two lines with lB =504nm(blue) and λR = 672 nm (red). This light is used to illuminate a 2-cm long diffraction grating. The first order (m=1) (1)  diffracted blue line is observed at θB =14 . (a) Find the spacing between the rulings of the grating. (b) Specify the diffraction angles of the blue and red lines for the first two orders. (c) How many lines will be observed for each color?