Carbon dioxide laser

Jump to navigation Jump to search


WikiDoc Resources for Carbon dioxide laser


Most recent articles on Carbon dioxide laser

Most cited articles on Carbon dioxide laser

Review articles on Carbon dioxide laser

Articles on Carbon dioxide laser in N Eng J Med, Lancet, BMJ


Powerpoint slides on Carbon dioxide laser

Images of Carbon dioxide laser

Photos of Carbon dioxide laser

Podcasts & MP3s on Carbon dioxide laser

Videos on Carbon dioxide laser

Evidence Based Medicine

Cochrane Collaboration on Carbon dioxide laser

Bandolier on Carbon dioxide laser

TRIP on Carbon dioxide laser

Clinical Trials

Ongoing Trials on Carbon dioxide laser at Clinical

Trial results on Carbon dioxide laser

Clinical Trials on Carbon dioxide laser at Google

Guidelines / Policies / Govt

US National Guidelines Clearinghouse on Carbon dioxide laser

NICE Guidance on Carbon dioxide laser


FDA on Carbon dioxide laser

CDC on Carbon dioxide laser


Books on Carbon dioxide laser


Carbon dioxide laser in the news

Be alerted to news on Carbon dioxide laser

News trends on Carbon dioxide laser


Blogs on Carbon dioxide laser


Definitions of Carbon dioxide laser

Patient Resources / Community

Patient resources on Carbon dioxide laser

Discussion groups on Carbon dioxide laser

Patient Handouts on Carbon dioxide laser

Directions to Hospitals Treating Carbon dioxide laser

Risk calculators and risk factors for Carbon dioxide laser

Healthcare Provider Resources

Symptoms of Carbon dioxide laser

Causes & Risk Factors for Carbon dioxide laser

Diagnostic studies for Carbon dioxide laser

Treatment of Carbon dioxide laser

Continuing Medical Education (CME)

CME Programs on Carbon dioxide laser


Carbon dioxide laser en Espanol

Carbon dioxide laser en Francais


Carbon dioxide laser in the Marketplace

Patents on Carbon dioxide laser

Experimental / Informatics

List of terms related to Carbon dioxide laser

The carbon dioxide laser (CO2 laser) was one of the earliest gas lasers to be developed (invented by Kumar Patel of Bell Labs in 1964[1]), and is still one of the most useful. Carbon dioxide lasers are the highest-power continuous wave lasers that are currently available. They are also quite efficient: the ratio of output power to pump power can be as large as 20%.

The CO2 laser produces a beam of infrared light with the principal wavelength bands centering around 9.4 and 10.6 micrometers.


A test target is vaporized and bursts into flame upon irradiation by a high power continuous wave carbon dioxide laser emitting tens of kilowatts of infrared light.

The active laser medium (laser gain/amplification medium) is a gas discharge which is air cooled (water cooled in higher power applications). The filling gas within the discharge tube consists primarily of:

The specific proportions vary according to the particular laser.

The population inversion in the laser is achieved by the following sequence:

  1. Electron impact excites vibrational motion of the nitrogen. Because nitrogen is a homonuclear molecule, it cannot lose this energy by photon emission, and its excited vibrational levels are therefore metastable and live for a long time.
  2. Collisional energy transfer between the nitrogen and the carbon dioxide molecule causes vibrational excitation of the carbon dioxide, with sufficient efficiency to lead to the desired population inversion necessary for laser operation.


Because CO2 lasers operate in the infrared, special materials are necessary for their construction. Typically, the mirrors are made of coated silicon, molybdenum, or gold, while windows and lenses are made of either germanium or zinc selenide. For high power applications, gold mirrors and zinc selenide windows and lenses are preferred. Historically, lenses and windows were made out of salt (either sodium chloride or potassium chloride). While the material was inexpensive, the lenses and windows degraded slowly with exposure to atmospheric moisture.

The most basic form of a CO2 laser consists of a gas discharge (with a mix close to that specified above) with a total reflector at one end, and an output coupler (usually a semi-reflective coated zinc selenide mirror) at the output end. The reflectivity of the output coupler is typically around 5-15%. The laser output may also be edge-coupled in higher power systems to reduce optical heating problems.

The CO2 laser can be constructed to have CW powers between milliwatts (mW) and hundreds of kilowatts (kW).[2] It is also very easy to actively Q-switch a CO2 laser by means of a rotating mirror or an electro-optic switch, giving rise to Q-switched peak powers up to gigawatts (GW) of peak power[3].

Because the laser transitions are actually on vibration-rotation bands of a linear triatomic molecule, the rotational structure of the P and R bands can be selected by a tuning element in the laser cavity. Because transmissive materials in the infrared are rather lossy, the frequency tuning element is almost always a diffraction grating. By rotating the diffraction grating, a particular rotational line of the vibrational transition can be selected. The finest frequency selection may also be obtained through the use of an etalon. In practice, together with isotopic substitution, this means that a continuous comb of frequencies separated by around 1 cm-1 (30 GHz) can be used that extend from 880 to 1090 cm-1. Such "line-tuneable" carbon dioxide lasers are principally of interest in research applications.


Because of the high power levels available (combined with reasonable cost for the laser), CO2 lasers are frequently used in industrial applications for cutting and welding, while lower power level lasers are used for engraving. They are also very useful in surgical procedures because water (which makes up most biological tissue) absorbs this frequency of light very well. Some examples of medical uses are laser surgery, skin resurfacing ("laser facelifts") (which essentially consist of burning the skin to promote collagen formation), and dermabrasion. Also, it could be used to treat certain skin conditions such as hirsuties papillaris genitalis by removing embarrassing or annoying bumps, podules, etc.

Because the atmosphere is quite transparent to infrared light, CO2 lasers are also used for military rangefinding using LIDAR techniques.

See also


  1. Patel, C. K. N. (1964). "Continuous-Wave Laser Action on Vibrational-Rotational Transitions of CO2". Physical Review. 136 (5A): A1187–A1193. doi:10.1103/PhysRev.136.A1187.
  2. Air Force Research Lab's 150 kW CO2 Laser
  3. Brookhaven National Lab's Carbon Dioxide Amplifier

External links

ca:Làser de diòxid de carboni de:Kohlendioxidlaser hr:CO2 laser nl:Koolstofdioxidelaser it:Laser ad anidride carbonica

Template:WikiDoc Sources