Discuss principle and working of carbon dioxide laser

CO2 Laser

The CO2 laser (carbon dioxide laser) is a molecular gas laser with emission in the long-wavelength infrared spectral region. It is based on a gas mixture as the gain medium, which contains carbon dioxide (CO2), helium (He), nitrogen (N2), and possibly some hydrogen (H2), oxygen (O2), water vapor and/or xenon (Xe). Such a laser is electrically pumped via an electrical gas discharge, which can be operated with DC current, with AC current (e.g. 20–50 kHz) or in the radio frequency (RF) domain.

Although direct excitation of CO2 molecules into the upper laser level is possible, it has proven to be most efficient to use a resonant energy transfer from nitrogen molecules. Here, nitrogen molecules are excited by the electric discharge into a metastable vibrational level and transfer their excitation energy to the CO2 molecules when colliding with them. The exited CO2 molecules then largely participate in the laser transition. Helium serves both to depopulate the lower laser level and to remove the heat. Other constituents such as hydrogen or water vapor can help (particularly in sealed-tube lasers) to reoxidize carbon monoxide (CO, formed in the discharge) to carbon dioxide.

Principle

The active medium is a gas mixture of CO2, N2 and He. The laser transition takes place between the vibrational states of CO2 molecules.

Energy states of CO2 molecules
Carbon dioxide (Co2) is a symmetric molecule (O=C=O) and it has three modes of vibration: 
  • Symmetric stretching.
  • Bending. 
  • Antisymmetric stretching is shown in the figure.

Symmetric stretching mode
In this mode of vibration, carbon atoms are at rest and both oxygen atoms vibrate simultaneously along the axis of the molecule departing or approaching the fixed carbon atoms.

Bending mode
In this mode of vibration, oxygen atoms and carbon atoms vibrate perpendicular to molecular axis.

Asymmetric stretching mode
In this mode of vibration, oxygen atoms and carbon atoms vibrate asymmetrically, i.e., oxygen atoms move in one direction while carbon atoms in the other direction.

Construction of Carbon Dioxide Laser

it consists of a tube 5m long and 2 cm in diameter. The discharge is produced by d.c excitation. The resonant cavity is formed of confocal silicon mirrors coated with aluminum. Pressured He is about 7 Torr, P (N2)~ 1.2 Torr, and P (CO2)~0.33 torr. The gain of E(0,0,1) – E (1,0,0) transition is higher, so laser oscillator at 10.6 µm.


To obtain an oscillation of 9.0 µm, some selective device such as a diffraction grating is placed in the cavity. The maximum power of this laser is about 50 – 60 w/m. CO2 lasers are widely used in the industries. 

Working of Carbon Dioxide Laser

To have a CO2 laser, a mixture of Co2 and N2 in the ratio of about 0.8:1 is filled in a gas discharge tube. Also, helium is part of the mixture. Helium is more than N2 in the mixture. Co2 molecule act as an active or laser medium and N2 molecule help in achieving the population inversion in the same way as helium is used in He-Ne laser.

When an electric discharge is passed through the tube, the number of electrons is emitted, which pumps nitrogen molecules to  V = 1 state.

In CO2 laser, the energy difference between the vibrational energy levels of Nitrogen and carbon dioxide is very small ( i.e. about 0.3 eV ) and hence there are a large number of electrons in the gas discharge tube having the energy of more than 0.3 eV. The energy levels of CO2 molecules are shown in the figure.


The vibrational state for N2 is a metastable state. Therefore, it provides a longer time for the collision between the excited N2 molecules and atom molecule of Co2 in the ground state.

As a result of this, the Co2 molecules are excited to the energy state E (0,0,1). Hence, population inversion is achieved as the number of CO2  molecules in the energy state E (0,0,1) are much more than the Co2 molecules in other vibrational states like E (1,0,0), E (0,0,2), and E (0,1,0).

Transition through stimulated emission process from energy level E (0,0,1) to the energy level E (1,0,0)and E (0,2,0) give rise to infrared Photons of wavelength10 µm and 9.6 µm respectively.

The function of adding Helium in the mixture of Co2 and N2 is many folds.
  • It influences the lifetime of the energy label and does not spoil the population inversion.
  • Helium has high thermal conductivity and so helps to conduct heat away to the walls of the tube keeping CO2 cold. In other words, helium helps to depopulate the lower level. 
Advantages of Carbon Dioxide Laser
  • The construction of CO2 laser is simple.
  • The output of this laser is continuous.
  • It has high efficiency.
  • It has very high output power.
  • The output power can be increased by extending the length of the gas tube.
Disadvantages of Carbon Dioxide Laser
  • The contamination of oxygen by carbon monoxide will have some effect on laser action.
  • The operating temperature plays an important role in determining the output power of laser.
  • The corrosion may occur at the reflecting plates.
  • Accidental exposure may damage our eyes since it is invisible (infrared region) to our eyes.

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