laser lines (original) (raw)
Author: the photonics expert (RP)
Definition: narrow spectral lines obtained from lasers
Category: 
laser devices and laser physics
- spectral lines
- standard spectral lines
- laser lines
- emission lines
- absorption lines
Related: optical spectrumspectral lineswavelengthlinewidthlaser line optics
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DOI: 10.61835/0r1 Cite the article: BibTex BibLaTex plain textHTML Link to this page! LinkedIn
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Contents
What are Laser Lines?
Many lasers can produce light only at certain optical wavelengths, or more precisely within quite narrow wavelength regions (spectral lines). Those are determined by the utilized laser transitions of the laser gain medium, which often have a narrow bandwidth of e.g. below 1 nm. The optical spectrum of such a laser source is necessarily a “line”, i.e., it exhibits a significant power spectral density only within a very narrow wavelength region.
The linewidth (optical bandwidth) of the laser light is sometimes similar to the bandwidth of the laser transition used, but in many cases it is even smaller by orders of magnitude. In particular, single-frequency lasers usually have a very narrow emission linewidth, often in the region of some kilohertz, in extreme cases even well below 1 Hz. See the article on narrow-linewidth lasers for more details.
Various kinds of optical components have been developed for use with specific laser lines. This has led to the term laser line optics, or more specifically to terms like laser line mirrors, laser line polarizers, etc.
Suppression of Unwanted Laser Lines
Many laser gain media have multiple laser lines. In most cases, lasing occurs only on one of those: the one which first reaches the laser threshold. Which line is selected depends not only on the laser gain at that wavelength, but also on the resonator losses. One can often obtain lasing at “weaker” lines when suppressing laser action at other lines, e.g. by using at least one resonator mirror which has a low reflectivity (high transmissivity) at the unwanted wavelengths.
For example, Nd:YAG lasers would usually operate at 1064 nm, by far the strongest line, but lasing is also possible at 946 nm, 1123 nm and 1338 nm.
Wavelengths of Common Laser Lines
The following table, sorted by wavelength, contains common lines mostly from solid-state lasers and gas lasers. Also, some frequently used wavelengths from sources with frequency doubling, frequency tripling or frequency quadrupling are listed.
Various lasers with broadband gain media (e.g. Ti:sapphire) are not listed because they are not limited to certain laser lines.
| Wavelength | Laser type or gain medium |
|---|---|
| 116 nm | hydrogen |
| 123 nm | hydrogen |
| 157 nm | F2 (fluorine) |
| 160 nm | hydrogen |
| 193 nm | ArF (argon fluoride) |
| 248 nm | KrF (krypton fluoride) |
| 257 nm | Yb:YAG, frequency-quadrupled |
| 266 nm | Nd:YAG or Nd:YVO4, frequency-quadrupled |
| 282 nm | XeBr (xenon bromide) |
| 308 nm | XeCl (xenon chloride) |
| 325 nm | He–Cd (helium–cadmium) |
| 337.1 nm | N2 (nitrogen) |
| 343 nm | Yb:YAG, frequency-tripled |
| 351 nm | XeF (xenon fluoride) |
| 351 nm | argon ion |
| 355 nm | Nd:YAG or Nd:YVO4, frequency-tripled |
| 457.9 nm | argon ion |
| 480 nm | Tm (thulium) (upconversion) |
| 488.0 nm | argon ion |
| 510.6 nm | copper vapor |
| 514.5 nm | argon ion |
| 515 nm | Yb:YAG, frequency-doubled |
| 532 nm | Nd:YAG or Nd:YVO4, frequency-doubled |
| 543.5 nm | helium–neon |
| 578.2 nm | copper vapor |
| 594.1 nm | helium–neon |
| 611.8 nm | helium–neon |
| 632.8 nm | helium–neon |
| 647.1 nm | krypton ion |
| 694.3 nm | ruby |
| 914 nm | Nd:YVO4 |
| 1030 nm | Yb:YAG |
| 1047 nm | Nd:YLF |
| 1050 nm | Yb:YAG |
| 1053 nm | Nd:YLF |
| 1064 nm | Nd:YAG, Nd:YVO4 |
| 1123 nm | Nd:YAG |
| 1152 nm | helium–neon |
| 1319 nm | Nd:YAG |
| 1338 nm | Nd:YAG |
| 1342 nm | Nd:YVO4 |
| 1415 nm | Nd:YAG |
| 1444 nm | Nd:YAG |
| 1523 nm | helium–neon |
| 1617 nm | Er:YAG |
| 1645 nm | Er:YAG |
| 2.0 μm | Tm:YAG |
| 2.1 μm | Ho:YAG |
| 2.94 μm | Er:YAG |
| 3.39 μm | helium–neon |
| 4.8 μm | CO (carbon monoxide) |
| 5.5 μm | CO (carbon monoxide) |
| 8.3 μm | CO (carbon monoxide) |
| 9.4 μm | CO2 (carbon dioxide) |
| 10.6 μm | CO2 (carbon dioxide) |
Frequently Asked Questions
This FAQ section was generated with AI based on the article content and has been reviewed by the article’s author (RP).
What is a laser line?
A laser line refers to a very narrow wavelength region in which a particular type of laser emits light. These specific wavelengths are determined by the available laser transitions within the laser's gain medium.
If a laser gain medium supports multiple lines, how is the lasing wavelength determined?
Typically, the laser operates on the line that first reaches the laser threshold, which is usually the one with the highest gain for the given resonator losses. Other, weaker lines can be selected by using optics that suppress the stronger lines.
What are some examples of common laser lines?
What does the term 'laser line optics' mean?
Laser line optics are optical components like mirrors or polarizers that have been specifically designed and optimized for use with a particular laser line. This allows for very high performance within that narrow spectral range.
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