Jump to content

Amplified spontaneous emission

From Wikipedia, the free encyclopedia
(Redirected from Superluminescence)

Amplified spontaneous emission (ASE) or superluminescence is light, produced by spontaneous emission, that has been optically amplified by the process of stimulated emission in a gain medium. It is inherent in the field of random lasers.

Origins

[edit]

ASE is produced when a laser gain medium is pumped to produce a population inversion. Feedback of the ASE by the laser's optical cavity may produce laser operation if the lasing threshold is reached. Excess ASE is an unwanted effect in lasers, since it is not coherent, and limits the maximum gain that can be achieved in the gain medium. ASE creates serious problems in any laser with high gain and/or large size. In this case, a mechanism to absorb or extract the incoherent ASE must be provided, otherwise the excitation of the gain medium will be depleted by the incoherent ASE rather than by the desired coherent laser radiation. ASE is especially problematic in lasers with short and wide optical cavities, such as disk lasers (active mirrors).[1]

ASE can also be a desirable effect, finding use in broadband light sources. If the cavity has no optical feedback, lasing will be inhibited, resulting in a broad emission bandwidth due to the bandwidth of the gain medium. This results in low temporal coherence, offering reduced speckle noise when compared with a laser. Spatial coherence can be high, however, allowing for tight focusing of the radiation. These characteristics make such sources useful for fiber optic systems and optical coherence tomography. Examples of such sources include superluminescent diodes and doped fiber amplifiers.

In organic dye lasers

[edit]

ASE in pulsed organic dye lasers can have very broad spectral characteristics (as much as 40–50 nm wide) and presents, as such, a serious challenge in the design and operation of tunable narrow-linewidth dye lasers. In order to suppress ASE, in favor of pure laser emission, researchers use various approaches including optimized laser cavity designs.[2]

In disk lasers: Controversy

[edit]

According to some publications, at the power scaling of disk lasers, the round-trip gain should be reduced,[3] which means hardening[clarification needed] of requirement on the background loss. Other researchers believe the existing disk lasers work far from such a limit, and the power scaling can be achieved without modification of existing laser materials.[4]

In self healing dye doped polymers

[edit]

In 2008, a group at Washington state university observed reversible photodegradation or simply, self healing in organic dyes like Disperse Orange 11[5] when doped in polymers. They used amplified spontaneous emission as a probe to study self healing properties.[6]

In high-power short-pulse laser systems

[edit]

In high-power CPA-laser systems with a peak power of several terawatt or petawatt, e.g. the POLARIS laser system, the ASE limits the temporal intensity contrast. After the compression of the laser pulse, which is temporally stretched during the amplification, the ASE causes a quasi-continuous pedestal which is partly located at times before the compressed laser pulse.[7] Due to the high intensities within the focal spot of up to 10^22 W/cm2 the ASE is often sufficient to significantly disturb the experiment or even make the desired laser-target interaction impossible.

See also

[edit]

References

[edit]
  1. ^ D. Kouznetsov; J.F. Bisson; K. Takaichi; K. Ueda (2005). "Single-mode solid-state laser with short wide unstable cavity". JOSA B. 22 (8): 1605–1619. Bibcode:2005JOSAB..22.1605K. doi:10.1364/JOSAB.22.001605.
  2. ^ F. J. Duarte (1990). "Narrow-linewidth pulsed dye laser oscillators". In F. J. Duarte; L. W. Hillman (eds.). Dye Laser Principles. Boston: Academic Press. pp. 133–183 and 254–259. ISBN 978-0-12-222700-4.
  3. ^ D. Kouznetsov; J.F. Bisson; J. Dong; K. Ueda (2006). "Surface loss limit of the power scaling of a thin-disk laser". JOSA B. 23 (6): 1074–1082. Bibcode:2006JOSAB..23.1074K. doi:10.1364/JOSAB.23.001074. Retrieved 2007-01-26.; [1][permanent dead link]
  4. ^ A. Giesen; H. Hügel; A. Voss; K. Wittig; U. Brauch; H. Opower (1994). "Scalable concept for diode-pumped high-power solid-state lasers". Applied Physics B. 58 (5): 365–372. Bibcode:1994ApPhB..58..365G. doi:10.1007/BF01081875. S2CID 121158745.
  5. ^ http://www.sigmaaldrich.com/catalog/ProductDetail.do?D7=0&N5=SEARCH_CONCAT_PNO|BRAND_KEY&N4=217093|SIAL&N25=0&QS=ON&F=SPEC Archived January 19, 2012, at the Wayback Machine
  6. ^ Natnael B. Embaye, Shiva K. Ramini, and Mark G. Kuzyk, J. Chem. Phys. 129, 054504 (2008) https://arxiv.org/abs/0808.3346
  7. ^ Keppler, Sebastian; Sävert, Alexander; Körner, Jörg; Hornung, Marco; Liebetrau, Hartmut; Hein, Joachim; Kaluza, Malte Christoph (2016-03-01). "The generation of amplified spontaneous emission in high-power CPA laser systems". Laser & Photonics Reviews. 10 (2): 264–277. Bibcode:2016LPRv...10..264K. doi:10.1002/lpor.201500186. ISSN 1863-8899. PMC 4845653. PMID 27134684.