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Dye laser

October 15, 2023

A dye laser is a laser that uses an organic dye as the lasing medium, usually as a liquid solution. Compared to gases and most solid state lasing media, a dye can usually be used for a much wider range of wavelengths, often spanning 50 to 100 nanometers or more. The wide bandwidth makes them particularly suitable for tunable lasers and pulsed lasers. The dye rhodamine 6G, for example, can be tuned from 635 nm (orangish-red) to 560 nm (greenish-yellow), and produce pulses as short as 16 femtoseconds.[1] Moreover, the dye can be replaced by another type in order to generate an even broader range of wavelengths with the same laser, from the near-infrared to the near-ultraviolet, although this usually requires replacing other optical components in the laser as well, such as dielectric mirrors or pump lasers.

Close-up of a table-top CW dye laser based on rhodamine 6G, emitting at 580 nm (yellow). The emitted laser beam is visible as faint yellow lines between the yellow window (center) and the yellow optics (upper-right), where it reflects down across the image to an unseen mirror, and back into the dye jet from the lower left corner. The orange dye-solution enters the laser from the left and exits to the right, still glowing from triplet phosphorescence, and is pumped by a 514 nm (blue-green) beam from an argon laser. The pump laser can be seen entering the dye jet, beneath the yellow window.

Dye lasers were independently discovered by P. P. Sorokin and F. P. Schäfer (and colleagues) in 1966.[2][3]

In addition to the usual liquid state, dye lasers are also available as solid state dye lasers (SSDL). These SSDL lasers use dye-doped organic matrices as gain medium.

Construction Edit

 
The internal cavity of a linear dye-laser, showing the beam path. The pump laser (green) enters the dye cell from the left. The emitted beam exits to the right (lower yellow beam) through a cavity dumper (not shown). A diffraction grating is used as the high-reflector (upper yellow beam, left side). The two meter beam is redirected several times by mirrors and prisms, which reduce the overall length, expand or focus the beam for various parts of the cavity, and eliminate one of two counter-propagating waves produced by the dye cell. The laser is capable of continuous wave operation or ultrashort picosecond pulses (trillionth of a second, equating to a beam less than 1/3 of a millimeter in length).
 
A ring dye laser. P-pump laser beam; G-gain dye jet; A-saturable absorber dye jet; M0, M1, M2-planar mirrors; OC–output coupler; CM1 to CM4-curved mirrors.

A dye laser uses a gain medium consisting of an organic dye, which is a carbon-based, soluble stain that is often fluorescent, such as the dye in a highlighter pen. The dye is mixed with a compatible solvent, allowing the molecules to diffuse evenly throughout the liquid. The dye solution may be circulated through a dye cell, or streamed through open air using a dye jet. A high energy source of light is needed to 'pump' the liquid beyond its lasing threshold. A fast discharge flashtube or an external laser is usually used for this purpose. Mirrors are also needed to oscillate the light produced by the dye's fluorescence, which is amplified with each pass through the liquid. The output mirror is normally around 80% reflective, while all other mirrors are usually more than 99.9% reflective. The dye solution is usually circulated at high speeds, to help avoid triplet absorption and to decrease degradation of the dye. A prism or diffraction grating is usually mounted in the beam path, to allow tuning of the beam.

Because the liquid medium of a dye laser can fit any shape, there are a multitude of different configurations that can be used. A Fabry–Pérot laser cavity is usually used for flashtube pumped lasers, which consists of two mirrors, which may be flat or curved, mounted parallel to each other with the laser medium in between. The dye cell is often a thin tube approximately equal in length to the flashtube, with both windows and an inlet/outlet for the liquid on each end. The dye cell is usually side-pumped, with one or more flashtubes running parallel to the dye cell in a reflector cavity. The reflector cavity is often water cooled, to prevent thermal shock in the dye caused by the large amounts of near-infrared radiation which the flashtube produces. Axial pumped lasers have a hollow, annular-shaped flashtube that surrounds the dye cell, which has lower inductance for a shorter flash, and improved transfer efficiency. Coaxial pumped lasers have an annular dye cell that surrounds the flashtube, for even better transfer efficiency, but have a lower gain due to diffraction losses. Flash pumped lasers can be used only for pulsed output applications.[4][5][6]

A ring laser design is often chosen for continuous operation, although a Fabry–Pérot design is sometimes used. In a ring laser, the mirrors of the laser are positioned to allow the beam to travel in a circular path. The dye cell, or cuvette, is usually very small. Sometimes a dye jet is used to help avoid reflection losses. The dye is usually pumped with an external laser, such as a nitrogen, excimer, or frequency doubled Nd:YAG laser. The liquid is circulated at very high speeds, to prevent triplet absorption from cutting off the beam.[7] Unlike Fabry–Pérot cavities, a ring laser does not generate standing waves which cause spatial hole burning, a phenomenon where energy becomes trapped in unused portions of the medium between the crests of the wave. This leads to a better gain from the lasing medium.[8][9]

Operation Edit

The dyes used in these lasers contain rather large organic molecules which fluoresce. Most dyes have a very short time between the absorption and emission of light, referred to as the fluorescence lifetime, which is often on the order of a few nanoseconds. (In comparison, most solid-state lasers have a fluorescence lifetime ranging from hundreds of microseconds to a few milliseconds.) Under standard laser-pumping conditions, the molecules emit their energy before a population inversion can properly build up, so dyes require rather specialized means of pumping. Liquid dyes have an extremely high lasing threshold. In addition, the large molecules are subject to complex excited state transitions during which the spin can be "flipped", quickly changing from the useful, fast-emitting "singlet" state to the slower "triplet" state.[10]

The incoming light excites the dye molecules into the state of being ready to emit stimulated radiation; the singlet state. In this state, the molecules emit light via fluorescence, and the dye is transparent to the lasing wavelength. Within a microsecond or less, the molecules will change to their triplet state. In the triplet state, light is emitted via phosphorescence, and the molecules absorb the lasing wavelength, making the dye partially opaque. Flashlamp-pumped lasers need a flash with an extremely short duration, to deliver the large amounts of energy necessary to bring the dye past threshold before triplet absorption overcomes singlet emission. Dye lasers with an external pump-laser can direct enough energy of the proper wavelength into the dye with a relatively small amount of input energy, but the dye must be circulated at high speeds to keep the triplet molecules out of the beam path. Due to their high absorption, the pumping energy may often be concentrated into a rather small volume of liquid.[11]

Since organic dyes tend to decompose under the influence of light, the dye solution is normally circulated from a large reservoir.[12] The dye solution can be flowing through a cuvette, i.e., a glass container, or be as a dye jet, i.e., as a sheet-like stream in open air from a specially-shaped nozzle. With a dye jet, one avoids reflection losses from the glass surfaces and contamination of the walls of the cuvette. These advantages come at the cost of a more-complicated alignment.

Liquid dyes have very high gain as laser media. The beam needs to make only a few passes through the liquid to reach full design power, and hence, the high transmittance of the output coupler. The high gain also leads to high losses, because reflections from the dye-cell walls or flashlamp reflector cause parasitic oscillations, dramatically reducing the amount of energy available to the beam. Pump cavities are often coated, anodized, or otherwise made of a material that will not reflect at the lasing wavelength while reflecting at the pump wavelength.[11]

A benefit of organic dyes is their high fluorescence efficiency. The greatest losses in many lasers and other fluorescence devices is not from the transfer efficiency (absorbed versus reflected/transmitted energy) or quantum yield (emitted number of photons per absorbed number), but from the losses when high-energy photons are absorbed and reemitted as photons of longer wavelengths. Because the energy of a photon is determined by its wavelength, the emitted photons will be of lower energy; a phenomenon called the Stokes shift. The absorption centers of many dyes are very close to the emission centers. Sometimes the two are close enough that the absorption profile slightly overlaps the emission profile. As a result, most dyes exhibit very small Stokes shifts and consequently allow for lower energy losses than many other laser types due to this phenomenon. The wide absorption profiles make them particularly suited to broadband pumping, such as from a flashtube. It also allows a wide range of pump lasers to be used for any certain dye and, conversely, many different dyes can be used with a single pump laser.[10]

  •  

    A cuvette used in a dye laser. A thin sheet of liquid is passed between the windows at high speeds. The windows are set at Brewster's angle (air-to-glass interface) for the pump laser, and at Brewster's angle (liquid-to-glass interface) for the emitted beam.

  •  

    Stokes shift in Rhodamine 6G during broadband absorption/emission. In laser operation, the Stokes shift is the difference between the pump wavelength and the output.

CW dye lasers Edit

Continuous-wave (CW) dye lasers[13] often use a dye jet. CW dye-lasers can have a linear or a ring cavity, and provided the foundation for the development of femtosecond lasers.

Narrow linewidth dye lasers Edit

 
Multiple prisms expand the beam in one direction, providing better illumination of a diffraction grating. Depending on the angle unwanted wavelengths are dispersed, so are used to tune the output of a dye laser, often to a linewidth of a fraction of an angstrom.

Dye lasers' emission is inherently broad. However, tunable narrow linewidth emission has been central to the success of the dye laser. In order to produce narrow bandwidth tuning these lasers use many types of cavities and resonators which include gratings, prisms, multiple-prism grating arrangements, and etalons.[14]

The first narrow linewidth dye laser, introduced by Hänsch, used a Galilean telescope as beam expander to illuminate the diffraction grating.[15] Next were the grazing-incidence grating designs[16][17] and the multiple-prism grating configurations.[18][19] The various resonators and oscillator designs developed for dye lasers have been successfully adapted to other laser types such as the diode laser.[20] The physics of narrow-linewidth multiple-prism grating lasers was explained by Duarte and Piper.[21]

Chemicals used Edit

 
Rhodamine 6G Chloride powder; mixed with methanol; emitting yellow light under the influence of a green laser

Some of the laser dyes are rhodamine (orange, 540–680 nm), fluorescein (green, 530–560 nm), coumarin (blue 490–620 nm), stilbene (violet 410–480 nm), umbelliferone (blue, 450–470 nm), tetracene, malachite green, and others.[22][23] While some dyes are actually used in food coloring, most dyes are very toxic, and often carcinogenic.[24] Many dyes, such as rhodamine 6G, (in its chloride form), can be very corrosive to all metals except stainless steel. Although dyes have very broad fluorescence spectra, the dye's absorption and emission will tend to center on a certain wavelength and taper off to each side, forming a tunability curve, with the absorption center being of a shorter wavelength than the emission center. Rhodamine 6G, for example, has its highest output around 590 nm, and the conversion efficiency lowers as the laser is tuned to either side of this wavelength.

A wide variety of solvents can be used, although most dyes will dissolve better in some solvents than in others. Some of the solvents used are water, glycol, ethanol, methanol, hexane, cyclohexane, cyclodextrin, and many others. Solvents can be highly toxic, and can sometimes be absorbed directly through the skin, or through inhaled vapors. Many solvents are also extremely flammable. The various solvents can also have an effect on the specific color of the dye solution, the lifetime of the singlet state, either enhancing or quenching the triplet state, and, thus, on the lasing bandwidth and power obtainable with a particular laser-pumping source.[10]

Adamantane is added to some dyes to prolong their life.

Cycloheptatriene and cyclooctatetraene (COT) can be added as triplet quenchers for rhodamine G, increasing the laser output power. Output power of 1.4 kilowatt at 585 nm was achieved using Rhodamine 6G with COT in methanol-water solution.

Excitation lasers Edit

Flashlamps and several types of lasers can be used to optically pump dye lasers. A partial list of excitation lasers include:[25]

Ultra-short optical pulses Edit

R. L. Fork, B. I. Greene, and C. V. Shank demonstrated, in 1981, the generation of ultra-short laser pulse using a ring-dye laser (or dye laser exploiting colliding pulse mode-locking). This kind of laser is capable of generating laser pulses of ~ 0.1 ps duration.[26]

The introduction of grating techniques and intra-cavity prismatic pulse compressors eventually resulted in the routine emission of femtosecond dye laser pulses.

Applications Edit

 
An atomic vapor laser isotope separation experiment at LLNL. Green light is from a copper vapor pump laser used to pump a highly tuned dye laser which is producing the orange light.

Dye lasers are very versatile. In addition to their recognized wavelength agility these lasers can offer very large pulsed energies or very high average powers. Flashlamp-pumped dye lasers have been shown to yield hundreds of Joules per pulse and copper-laser-pumped dye lasers are known to yield average powers in the kilowatt regime.[27]

Dye lasers are used in many applications including:

In laser medicine these lasers are applied in several areas,[31][32] including dermatology where they are used to make skin tone more even. The wide range of wavelengths possible allows very close matching to the absorption lines of certain tissues, such as melanin or hemoglobin, while the narrow bandwidth obtainable helps reduce the possibility of damage to the surrounding tissue. They are used to treat port-wine stains and other blood vessel disorders, scars and kidney stones. They can be matched to a variety of inks for tattoo removal, as well as a number of other applications.[33]

In spectroscopy, dye lasers can be used to study the absorption and emission spectra of various materials. Their tunability, (from the near-infrared to the near-ultraviolet), narrow bandwidth, and high intensity allows a much greater diversity than other light sources. The variety of pulse widths, from ultra-short, femtosecond pulses to continuous-wave operation, makes them suitable for a wide range of applications, from the study of fluorescent lifetimes and semiconductor properties to lunar laser ranging experiments.[34]

Tunable lasers are used in swept-frequency metrology to enable measurement of absolute distances with very high accuracy. A two axis interferometer is set up and by sweeping the frequency, the frequency of the light returning from the fixed arm is slightly different from the frequency returning from the distance measuring arm. This produces a beat frequency which can be detected and used to determine the absolute difference between the lengths of the two arms.[35]

See also Edit

References Edit

  1. ^ Dye Laser Principles: With Applications by Frank J. Duarte, Lloyd W. Hillman -- Academic Press 1990 Page 42
  2. ^ F. P. Schäfer (Ed.), Dye Lasers (Springer-Verlag, Berlin, 1990).
  3. ^ F. J. Duarte and L. W. Hillman (Eds.), Dye Laser Principles (Academic, New York, 1990).
  4. ^ Design and Analysis of Flashlamp Systems for Pumping Organic Dye Lasers – J. F. Holzrichter and A. L. Schawlow. Annals of the New York Academy of Sciences
  5. ^ Yee, T. K.; Fan, B.; Gustafson, T. K. (1979-04-15). "Simmer-enhanced flashlamp-pumped dye laser". Applied Optics. The Optical Society. 18 (8): 1131–2. Bibcode:1979ApOpt..18.1131Y. doi:10.1364/ao.18.001131. ISSN 0003-6935. PMID 20208893.
  6. ^ "General Xenon Flash and Strobe Design Guidelines". members.misty.com. Retrieved 19 April 2018.
  7. ^ "Sam's Laser FAQ - Home-Built Dye Laser". www.repairfaq.org. Retrieved 19 April 2018.
  8. ^ Paschotta, Dr. Rüdiger. "Encyclopedia of Laser Physics and Technology - spatial hole burning, SHB, laser, single-frequency operation". www.rp-photonics.com. Retrieved 19 April 2018.
  9. ^ Laser fundamentals by William T. Silfvast – Cambridge University Press 1996 Page 397-399
  10. ^ a b c (PDF). Archived from the original (PDF) on 2017-02-16. Retrieved 2017-02-13.{{cite web}}: CS1 maint: archived copy as title (link)
  11. ^ a b "Principles of Lasers", by Orazio Svelto
  12. ^ F. P. Schäfer and K. H. Drexhage, Dye Lasers., 2nd rev. ed., vol. 1, Berlin ; New York: Springer-Verlag, 1977
  13. ^ O. G. Peterson, S. A. Tuccio, B. B. Snavely, "CW operation of an organic dye solution laser", Appl. Phys. Lett. 42, 1917-1918 (1970).
  14. ^ F. J. Duarte and L. W. Hillman, Dye Laser Principles (Academic, New York, 1990) Chapter 4.
  15. ^ T. W. Hänsch, Repetitively Pulsed Tunable Dye Laser for High Resolution Spectroscopy, Appl. Opt. 11, 895-898 (1972).
  16. ^ I. Shoshan, N. N. Danon, and U. P. Oppenheim, Narrowband operation of a pulsed dye laser without intracavity beam expansion, J. Appl. Phys. 48, 4495-4497 (1977).
  17. ^ Littman, Michael G.; Metcalf, Harold J. (1978-07-15). "Spectrally narrow pulsed dye laser without beam expander". Applied Optics. The Optical Society. 17 (14): 2224–7. Bibcode:1978ApOpt..17.2224L. doi:10.1364/ao.17.002224. ISSN 0003-6935. PMID 20203761.
  18. ^ Duarte, F.J.; Piper, J.A. (1980). "A double-prism beam expander for pulsed dye lasers". Optics Communications. Elsevier BV. 35 (1): 100–104. Bibcode:1980OptCo..35..100D. doi:10.1016/0030-4018(80)90368-5. ISSN 0030-4018.
  19. ^ Duarte, F. J.; Piper, J. A. (1981-06-15). "Prism preexpanded grazing-incidence grating cavity for pulsed dye lasers". Applied Optics. The Optical Society. 20 (12): 2113–6. Bibcode:1981ApOpt..20.2113D. doi:10.1364/ao.20.002113. ISSN 0003-6935. PMID 20332895.
  20. ^ P. Zorabedian, Tunable external cavity semiconductor lasers, in Tunable Lasers Handbook, F. J. Duarte (Ed.) (Academic, New York, 1995) Chapter 8.
  21. ^ Duarte, F.J.; Piper, J.A. (1982). "Dispersion theory of multiple-prism beam expanders for pulsed dye lasers". Optics Communications. Elsevier BV. 43 (5): 303–307. Bibcode:1982OptCo..43..303D. doi:10.1016/0030-4018(82)90216-4. ISSN 0030-4018.
  22. ^ Amnon Yariv, Optical Electronics in Modern Communications, Fifth Edition, page 266
  23. ^ http://www.exciton.com/pdfs/SpecPhys.pdf[bare URL PDF]
  24. ^ (PDF). Archived from the original (PDF) on 2015-02-21. Retrieved 2012-08-15.{{cite web}}: CS1 maint: archived copy as title (link)
  25. ^ F. J. Duarte and L. W. Hillman (Eds.), Dye Laser Principles (Academic, New York, 1990) Chapters 5 and 6.
  26. ^ Fork, R. L.; Greene, B. I.; Shank, C. V. (1981). "Generation of optical pulses shorter than 0.1 psec by colliding pulse mode locking". Applied Physics Letters. AIP Publishing. 38 (9): 671–672. Bibcode:1981ApPhL..38..671F. doi:10.1063/1.92500. ISSN 0003-6951. S2CID 45813878.
  27. ^ "HIGH POWER DYE LASERS". www.tunablelasers.com. Retrieved 19 April 2018.
  28. ^ M. A. Akerman, Dye laser isotope separation, in Dye Laser Principles, F. J. Duarte and L. W. Hillman (eds.)(Academic, New York, 1990) Chapter 9.
  29. ^ D. Klick, Industrial applications of dye lasers, in Dye Laser Principles, F. J. Duarte and L. W. Hillman (eds.)(Academic, New York, 1990) Chapter 8.
  30. ^ W. Demtröder, Laser Spectroscopy, 3rd Ed. (Springer, 2003).
  31. ^ L. Goldman, Dye lasers in medicine, in Dye Laser Principles, F. J. Duarte and L. W. Hillman, Eds. (Academic, New York, 1990) Chapter 10.
  32. ^ Costela A, Garcia-Moreno I, Gomez C (2016). "Medical Applications of Organic Dye Lasers". In Duarte FJ (ed.). Tunable Laser Applications (3rd ed.). Boca Raton: CRC Press. pp. 293–313. ISBN 9781482261066.
  33. ^ Duarte FJ, ed. (2016). Tunable Laser Applications (3rd ed.). Boca Raton: CRC Press. ISBN 9781482261066.
  34. ^ The Laser Guidebook By Jeff Hecht – McGraw Hill 1992 Page 294
  35. ^ (PDF). nasa.gov. Archived from the original (PDF) on 7 September 2012. Retrieved 19 April 2018.

External links Edit

  •   Media related to Dye lasers at Wikimedia Commons

October 15, 2023
laser, laser, laser, that, uses, organic, lasing, medium, usually, liquid, solution, compared, gases, most, solid, state, lasing, media, usually, used, much, wider, range, wavelengths, often, spanning, nanometers, more, wide, bandwidth, makes, them, particular. A dye laser is a laser that uses an organic dye as the lasing medium usually as a liquid solution Compared to gases and most solid state lasing media a dye can usually be used for a much wider range of wavelengths often spanning 50 to 100 nanometers or more The wide bandwidth makes them particularly suitable for tunable lasers and pulsed lasers The dye rhodamine 6G for example can be tuned from 635 nm orangish red to 560 nm greenish yellow and produce pulses as short as 16 femtoseconds 1 Moreover the dye can be replaced by another type in order to generate an even broader range of wavelengths with the same laser from the near infrared to the near ultraviolet although this usually requires replacing other optical components in the laser as well such as dielectric mirrors or pump lasers Close up of a table top CW dye laser based on rhodamine 6G emitting at 580 nm yellow The emitted laser beam is visible as faint yellow lines between the yellow window center and the yellow optics upper right where it reflects down across the image to an unseen mirror and back into the dye jet from the lower left corner The orange dye solution enters the laser from the left and exits to the right still glowing from triplet phosphorescence and is pumped by a 514 nm blue green beam from an argon laser The pump laser can be seen entering the dye jet beneath the yellow window Dye lasers were independently discovered by P P Sorokin and F P Schafer and colleagues in 1966 2 3 In addition to the usual liquid state dye lasers are also available as solid state dye lasers SSDL These SSDL lasers use dye doped organic matrices as gain medium Contents 1 Construction 2 Operation 3 CW dye lasers 4 Narrow linewidth dye lasers 5 Chemicals used 6 Excitation lasers 7 Ultra short optical pulses 8 Applications 9 See also 10 References 11 External linksConstruction Edit nbsp The internal cavity of a linear dye laser showing the beam path The pump laser green enters the dye cell from the left The emitted beam exits to the right lower yellow beam through a cavity dumper not shown A diffraction grating is used as the high reflector upper yellow beam left side The two meter beam is redirected several times by mirrors and prisms which reduce the overall length expand or focus the beam for various parts of the cavity and eliminate one of two counter propagating waves produced by the dye cell The laser is capable of continuous wave operation or ultrashort picosecond pulses trillionth of a second equating to a beam less than 1 3 of a millimeter in length nbsp A ring dye laser P pump laser beam G gain dye jet A saturable absorber dye jet M0 M1 M2 planar mirrors OC output coupler CM1 to CM4 curved mirrors A dye laser uses a gain medium consisting of an organic dye which is a carbon based soluble stain that is often fluorescent such as the dye in a highlighter pen The dye is mixed with a compatible solvent allowing the molecules to diffuse evenly throughout the liquid The dye solution may be circulated through a dye cell or streamed through open air using a dye jet A high energy source of light is needed to pump the liquid beyond its lasing threshold A fast discharge flashtube or an external laser is usually used for this purpose Mirrors are also needed to oscillate the light produced by the dye s fluorescence which is amplified with each pass through the liquid The output mirror is normally around 80 reflective while all other mirrors are usually more than 99 9 reflective The dye solution is usually circulated at high speeds to help avoid triplet absorption and to decrease degradation of the dye A prism or diffraction grating is usually mounted in the beam path to allow tuning of the beam Because the liquid medium of a dye laser can fit any shape there are a multitude of different configurations that can be used A Fabry Perot laser cavity is usually used for flashtube pumped lasers which consists of two mirrors which may be flat or curved mounted parallel to each other with the laser medium in between The dye cell is often a thin tube approximately equal in length to the flashtube with both windows and an inlet outlet for the liquid on each end The dye cell is usually side pumped with one or more flashtubes running parallel to the dye cell in a reflector cavity The reflector cavity is often water cooled to prevent thermal shock in the dye caused by the large amounts of near infrared radiation which the flashtube produces Axial pumped lasers have a hollow annular shaped flashtube that surrounds the dye cell which has lower inductance for a shorter flash and improved transfer efficiency Coaxial pumped lasers have an annular dye cell that surrounds the flashtube for even better transfer efficiency but have a lower gain due to diffraction losses Flash pumped lasers can be used only for pulsed output applications 4 5 6 A ring laser design is often chosen for continuous operation although a Fabry Perot design is sometimes used In a ring laser the mirrors of the laser are positioned to allow the beam to travel in a circular path The dye cell or cuvette is usually very small Sometimes a dye jet is used to help avoid reflection losses The dye is usually pumped with an external laser such as a nitrogen excimer or frequency doubled Nd YAG laser The liquid is circulated at very high speeds to prevent triplet absorption from cutting off the beam 7 Unlike Fabry Perot cavities a ring laser does not generate standing waves which cause spatial hole burning a phenomenon where energy becomes trapped in unused portions of the medium between the crests of the wave This leads to a better gain from the lasing medium 8 9 Operation EditThe dyes used in these lasers contain rather large organic molecules which fluoresce Most dyes have a very short time between the absorption and emission of light referred to as the fluorescence lifetime which is often on the order of a few nanoseconds In comparison most solid state lasers have a fluorescence lifetime ranging from hundreds of microseconds to a few milliseconds Under standard laser pumping conditions the molecules emit their energy before a population inversion can properly build up so dyes require rather specialized means of pumping Liquid dyes have an extremely high lasing threshold In addition the large molecules are subject to complex excited state transitions during which the spin can be flipped quickly changing from the useful fast emitting singlet state to the slower triplet state 10 The incoming light excites the dye molecules into the state of being ready to emit stimulated radiation the singlet state In this state the molecules emit light via fluorescence and the dye is transparent to the lasing wavelength Within a microsecond or less the molecules will change to their triplet state In the triplet state light is emitted via phosphorescence and the molecules absorb the lasing wavelength making the dye partially opaque Flashlamp pumped lasers need a flash with an extremely short duration to deliver the large amounts of energy necessary to bring the dye past threshold before triplet absorption overcomes singlet emission Dye lasers with an external pump laser can direct enough energy of the proper wavelength into the dye with a relatively small amount of input energy but the dye must be circulated at high speeds to keep the triplet molecules out of the beam path Due to their high absorption the pumping energy may often be concentrated into a rather small volume of liquid 11 Since organic dyes tend to decompose under the influence of light the dye solution is normally circulated from a large reservoir 12 The dye solution can be flowing through a cuvette i e a glass container or be as a dye jet i e as a sheet like stream in open air from a specially shaped nozzle With a dye jet one avoids reflection losses from the glass surfaces and contamination of the walls of the cuvette These advantages come at the cost of a more complicated alignment Liquid dyes have very high gain as laser media The beam needs to make only a few passes through the liquid to reach full design power and hence the high transmittance of the output coupler The high gain also leads to high losses because reflections from the dye cell walls or flashlamp reflector cause parasitic oscillations dramatically reducing the amount of energy available to the beam Pump cavities are often coated anodized or otherwise made of a material that will not reflect at the lasing wavelength while reflecting at the pump wavelength 11 A benefit of organic dyes is their high fluorescence efficiency The greatest losses in many lasers and other fluorescence devices is not from the transfer efficiency absorbed versus reflected transmitted energy or quantum yield emitted number of photons per absorbed number but from the losses when high energy photons are absorbed and reemitted as photons of longer wavelengths Because the energy of a photon is determined by its wavelength the emitted photons will be of lower energy a phenomenon called the Stokes shift The absorption centers of many dyes are very close to the emission centers Sometimes the two are close enough that the absorption profile slightly overlaps the emission profile As a result most dyes exhibit very small Stokes shifts and consequently allow for lower energy losses than many other laser types due to this phenomenon The wide absorption profiles make them particularly suited to broadband pumping such as from a flashtube It also allows a wide range of pump lasers to be used for any certain dye and conversely many different dyes can be used with a single pump laser 10 nbsp A cuvette used in a dye laser A thin sheet of liquid is passed between the windows at high speeds The windows are set at Brewster s angle air to glass interface for the pump laser and at Brewster s angle liquid to glass interface for the emitted beam nbsp Stokes shift in Rhodamine 6G during broadband absorption emission In laser operation the Stokes shift is the difference between the pump wavelength and the output CW dye lasers EditContinuous wave CW dye lasers 13 often use a dye jet CW dye lasers can have a linear or a ring cavity and provided the foundation for the development of femtosecond lasers Narrow linewidth dye lasers Edit nbsp Multiple prisms expand the beam in one direction providing better illumination of a diffraction grating Depending on the angle unwanted wavelengths are dispersed so are used to tune the output of a dye laser often to a linewidth of a fraction of an angstrom Dye lasers emission is inherently broad However tunable narrow linewidth emission has been central to the success of the dye laser In order to produce narrow bandwidth tuning these lasers use many types of cavities and resonators which include gratings prisms multiple prism grating arrangements and etalons 14 The first narrow linewidth dye laser introduced by Hansch used a Galilean telescope as beam expander to illuminate the diffraction grating 15 Next were the grazing incidence grating designs 16 17 and the multiple prism grating configurations 18 19 The various resonators and oscillator designs developed for dye lasers have been successfully adapted to other laser types such as the diode laser 20 The physics of narrow linewidth multiple prism grating lasers was explained by Duarte and Piper 21 Chemicals used Edit nbsp Rhodamine 6G Chloride powder mixed with methanol emitting yellow light under the influence of a green laserSome of the laser dyes are rhodamine orange 540 680 nm fluorescein green 530 560 nm coumarin blue 490 620 nm stilbene violet 410 480 nm umbelliferone blue 450 470 nm tetracene malachite green and others 22 23 While some dyes are actually used in food coloring most dyes are very toxic and often carcinogenic 24 Many dyes such as rhodamine 6G in its chloride form can be very corrosive to all metals except stainless steel Although dyes have very broad fluorescence spectra the dye s absorption and emission will tend to center on a certain wavelength and taper off to each side forming a tunability curve with the absorption center being of a shorter wavelength than the emission center Rhodamine 6G for example has its highest output around 590 nm and the conversion efficiency lowers as the laser is tuned to either side of this wavelength A wide variety of solvents can be used although most dyes will dissolve better in some solvents than in others Some of the solvents used are water glycol ethanol methanol hexane cyclohexane cyclodextrin and many others Solvents can be highly toxic and can sometimes be absorbed directly through the skin or through inhaled vapors Many solvents are also extremely flammable The various solvents can also have an effect on the specific color of the dye solution the lifetime of the singlet state either enhancing or quenching the triplet state and thus on the lasing bandwidth and power obtainable with a particular laser pumping source 10 Adamantane is added to some dyes to prolong their life Cycloheptatriene and cyclooctatetraene COT can be added as triplet quenchers for rhodamine G increasing the laser output power Output power of 1 4 kilowatt at 585 nm was achieved using Rhodamine 6G with COT in methanol water solution Excitation lasers EditFlashlamps and several types of lasers can be used to optically pump dye lasers A partial list of excitation lasers include 25 Copper vapor lasers Diode lasers Excimer lasers Nd YAG lasers mainly second and third harmonics Nitrogen lasers Ruby lasers Argon ion lasers in the CW regime Krypton ion lasers in the CW regimeUltra short optical pulses EditR L Fork B I Greene and C V Shank demonstrated in 1981 the generation of ultra short laser pulse using a ring dye laser or dye laser exploiting colliding pulse mode locking This kind of laser is capable of generating laser pulses of 0 1 ps duration 26 The introduction of grating techniques and intra cavity prismatic pulse compressors eventually resulted in the routine emission of femtosecond dye laser pulses Applications Edit nbsp An atomic vapor laser isotope separation experiment at LLNL Green light is from a copper vapor pump laser used to pump a highly tuned dye laser which is producing the orange light Dye lasers are very versatile In addition to their recognized wavelength agility these lasers can offer very large pulsed energies or very high average powers Flashlamp pumped dye lasers have been shown to yield hundreds of Joules per pulse and copper laser pumped dye lasers are known to yield average powers in the kilowatt regime 27 Dye lasers are used in many applications including astronomy as laser guide stars atomic vapor laser isotope separation 28 manufacturing 29 medicine spectroscopy 30 In laser medicine these lasers are applied in several areas 31 32 including dermatology where they are used to make skin tone more even The wide range of wavelengths possible allows very close matching to the absorption lines of certain tissues such as melanin or hemoglobin while the narrow bandwidth obtainable helps reduce the possibility of damage to the surrounding tissue They are used to treat port wine stains and other blood vessel disorders scars and kidney stones They can be matched to a variety of inks for tattoo removal as well as a number of other applications 33 In spectroscopy dye lasers can be used to study the absorption and emission spectra of various materials Their tunability from the near infrared to the near ultraviolet narrow bandwidth and high intensity allows a much greater diversity than other light sources The variety of pulse widths from ultra short femtosecond pulses to continuous wave operation makes them suitable for a wide range of applications from the study of fluorescent lifetimes and semiconductor properties to lunar laser ranging experiments 34 Tunable lasers are used in swept frequency metrology to enable measurement of absolute distances with very high accuracy A two axis interferometer is set up and by sweeping the frequency the frequency of the light returning from the fixed arm is slightly different from the frequency returning from the distance measuring arm This produces a beat frequency which can be detected and used to determine the absolute difference between the lengths of the two arms 35 See also EditLaser dye Dye used as a laser medium Organic laser Laser that uses a carbon based material as the gain medium Solid state dye laser Tunable laser laser whose wavelength can be alteredPages displaying wikidata descriptions as a fallbackReferences Edit Dye Laser Principles With Applications by Frank J Duarte Lloyd W Hillman Academic Press 1990 Page 42 F P Schafer Ed Dye Lasers Springer Verlag Berlin 1990 F J Duarte and L W Hillman Eds Dye Laser Principles Academic New York 1990 Design and Analysis of Flashlamp Systems for Pumping Organic Dye Lasers J F Holzrichter and A L Schawlow Annals of the New York Academy of Sciences Yee T K Fan B Gustafson T K 1979 04 15 Simmer enhanced flashlamp pumped dye laser Applied Optics The Optical Society 18 8 1131 2 Bibcode 1979ApOpt 18 1131Y doi 10 1364 ao 18 001131 ISSN 0003 6935 PMID 20208893 General Xenon Flash and Strobe Design Guidelines members misty com Retrieved 19 April 2018 Sam s Laser FAQ Home Built Dye Laser www repairfaq org Retrieved 19 April 2018 Paschotta Dr Rudiger Encyclopedia of Laser Physics and Technology spatial hole burning SHB laser single frequency operation www rp photonics com Retrieved 19 April 2018 Laser fundamentals by William T Silfvast Cambridge University Press 1996 Page 397 399 a b c Archived copy PDF Archived from the original PDF on 2017 02 16 Retrieved 2017 02 13 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link a b Principles of Lasers by Orazio Svelto F P Schafer and K H Drexhage Dye Lasers 2nd rev ed vol 1 Berlin New York Springer Verlag 1977 O G Peterson S A Tuccio B B Snavely CW operation of an organic dye solution laser Appl Phys Lett 42 1917 1918 1970 F J Duarte and L W Hillman Dye Laser Principles Academic New York 1990 Chapter 4 T W Hansch Repetitively Pulsed Tunable Dye Laser for High Resolution Spectroscopy Appl Opt 11 895 898 1972 I Shoshan N N Danon and U P Oppenheim Narrowband operation of a pulsed dye laser without intracavity beam expansion J Appl Phys 48 4495 4497 1977 Littman Michael G Metcalf Harold J 1978 07 15 Spectrally narrow pulsed dye laser without beam expander Applied Optics The Optical Society 17 14 2224 7 Bibcode 1978ApOpt 17 2224L doi 10 1364 ao 17 002224 ISSN 0003 6935 PMID 20203761 Duarte F J Piper J A 1980 A double prism beam expander for pulsed dye lasers Optics Communications Elsevier BV 35 1 100 104 Bibcode 1980OptCo 35 100D doi 10 1016 0030 4018 80 90368 5 ISSN 0030 4018 Duarte F J Piper J A 1981 06 15 Prism preexpanded grazing incidence grating cavity for pulsed dye lasers Applied Optics The Optical Society 20 12 2113 6 Bibcode 1981ApOpt 20 2113D doi 10 1364 ao 20 002113 ISSN 0003 6935 PMID 20332895 P Zorabedian Tunable external cavity semiconductor lasers in Tunable Lasers Handbook F J Duarte Ed Academic New York 1995 Chapter 8 Duarte F J Piper J A 1982 Dispersion theory of multiple prism beam expanders for pulsed dye lasers Optics Communications Elsevier BV 43 5 303 307 Bibcode 1982OptCo 43 303D doi 10 1016 0030 4018 82 90216 4 ISSN 0030 4018 Amnon Yariv Optical Electronics in Modern Communications Fifth Edition page 266 http www exciton com pdfs SpecPhys pdf bare URL PDF Archived copy PDF Archived from the original PDF on 2015 02 21 Retrieved 2012 08 15 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link F J Duarte and L W Hillman Eds Dye Laser Principles Academic New York 1990 Chapters 5 and 6 Fork R L Greene B I Shank C V 1981 Generation of optical pulses shorter than 0 1 psec by colliding pulse mode locking Applied Physics Letters AIP Publishing 38 9 671 672 Bibcode 1981ApPhL 38 671F doi 10 1063 1 92500 ISSN 0003 6951 S2CID 45813878 HIGH POWER DYE LASERS www tunablelasers com Retrieved 19 April 2018 M A Akerman Dye laser isotope separation in Dye Laser Principles F J Duarte and L W Hillman eds Academic New York 1990 Chapter 9 D Klick Industrial applications of dye lasers in Dye Laser Principles F J Duarte and L W Hillman eds Academic New York 1990 Chapter 8 W Demtroder Laser Spectroscopy 3rd Ed Springer 2003 L Goldman Dye lasers in medicine in Dye Laser Principles F J Duarte and L W Hillman Eds Academic New York 1990 Chapter 10 Costela A Garcia Moreno I Gomez C 2016 Medical Applications of Organic Dye Lasers In Duarte FJ ed Tunable Laser Applications 3rd ed Boca Raton CRC Press pp 293 313 ISBN 9781482261066 Duarte FJ ed 2016 Tunable Laser Applications 3rd ed Boca Raton CRC Press ISBN 9781482261066 The Laser Guidebook By Jeff Hecht McGraw Hill 1992 Page 294 Highly linear Widerange Swept Frequency Generation at Microwave and Optical Frequencies PDF nasa gov Archived from the original PDF on 7 September 2012 Retrieved 19 April 2018 External links Edit nbsp Media related to Dye lasers at Wikimedia Commons Retrieved from https en wikipedia org w index php title Dye laser amp oldid 1160186260, wikipedia, wiki, book, books, library,

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