CN202957448U - Middle and far-infrared super-continuum spectrum fiber laser - Google Patents
Middle and far-infrared super-continuum spectrum fiber laser Download PDFInfo
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- CN202957448U CN202957448U CN 201220470616 CN201220470616U CN202957448U CN 202957448 U CN202957448 U CN 202957448U CN 201220470616 CN201220470616 CN 201220470616 CN 201220470616 U CN201220470616 U CN 201220470616U CN 202957448 U CN202957448 U CN 202957448U
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Abstract
A middle and far-infrared super-continuum spectrum fiber laser of the utility model relates to the laser photoelectron field, and comprises a pulse fiber laser, a quartz photonic crystal fiber, a passive middle infrared chalcogenide glass fiber, a passive middle and far-infrared chalcogenide glass fiber, a filter, an excitation source and a chalcogenide glass fiber in which rare earth ions are doped. A pulse laser sent out by the pulse fiber laser generates a super-continuum spectrum laser via the quartz photonic crystal fiber to excite the passive middle infrared chalcogenide glass fiber to generate a middle infrared super-continuum spectrum laser, and the middle infrared super-continuum spectrum laser is filtered by the filter to be used as a seed source laser, and then the middle infrared super-continuum spectrum laser is amplified by the chalcogenide glass fiber in which rare earth ions are doped, and finally the amplified middle infrared super-continuum spectrum laser excites the passive middle and far-infrared chalcogenide glass fiber to generate a middle and far-infrared super-continuum spectrum laser of which the wavelength is between 5 and 14 micrometers. The middle and far-infrared super-continuum spectrum fiber laser of the utility model solves the problem that the middle and far-infrared laser light source is lacking, and enables the middle and far-infrared super-continuum spectrum laser output to be realized.
Description
Technical field
The utility model relates to the laser optoelectronic technical field, relates in particular to a kind of mid and far infrared optical fiber laser with super continuous spectrum.
Background technology
The higher spectrum segment of transmitance calls atmospheric window when usually sunlight being seen through atmosphere.The spectrum segment of atmospheric window mainly contains: and microwave band (300 ~ 1GHz/0.8 ~ 2.5cm), mid and far infrared wave band (8 ~ 14 μ m), middle-infrared band (3.5 ~ 5.5 μ m), near ultraviolet, visible light and near infrared band (0.3 ~ 1.3 μ m, 1.5 ~ 1.8 μ m).
Utilize at present the types such as solid state laser, semiconductor laser, gas laser can be easy to be implemented in the Laser output of visible light and near infrared band (0.3 ~ 1.3 μ m, 1.5 ~ 1.8 μ m), can be applied to the various fields such as national defence, industry, medical treatment.The laser that is positioned at the far atmospheric window wavelength of the middle-infrared band of atmospheric window wavelength 3-5 μ m and 8-1 4 μ m can be used for infrared tracking, interference, the navigation of search target and optical remote sensing to be surveyed, and national security is had vital meaning.Owing to the reasons such as scarcity of narrow bandgap semiconductor material, at present at middle infrared wavelength high efficiency transmitting illuminant and laser critical shortage.Utilize at present the optical parametric oscillator method, difference frequency generation, quantum cascade laser and gas laser can be realized low power 3 ~ 5 μ m Laser outputs, and the method that realizes at present mid and far infrared wave band (8 ~ 14 μ m) atmospheric window laser rarely has report, comparatively the CO that only has single wavelength (10.6 μ m) of maturation and energy extensive use
2Gas laser.As everyone knows, the shortcoming of gas laser is that electro-optical efficiency is low, and is bulky, uses inconvenience, and CO
2Gas laser need to use the high-tension electricity excitation, thereby has limited its application.
Therefore, instantly need a urgent problem that solves to be exactly: how can propose the lasing light emitter of a kind of effective generation mid and far infrared wave band (8 ~ 14 μ m), avoid using gas laser, realize mid and far infrared wave band (8 ~ 14 μ m) Laser output.
The utility model content
The utility model provides a kind of mid and far infrared optical fiber laser with super continuous spectrum, in order to solve the problem of present mid and far infrared LASER Light Source shortage, realizes mid and far infrared super continuous spectrums Laser output.
In order to solve the problems of the technologies described above, the utility model provides a kind of mid and far infrared optical fiber laser with super continuous spectrum, comprise pulse optical fiber, quartzy photonic crystal fiber, infrared chalcogenide glass fiber in passive, passive mid and far infrared chalcogenide glass fiber, filter, the chalcogenide glass fiber of driving source and doping with rare-earth ions, described driving source is used for the chalcogenide glass fiber of excitation doping with rare-earth ions, wherein, the pulse laser that pulse optical fiber sends, producing wave-length coverage by quartzy photonic crystal fiber is the super continuous spectrums laser of 1000 ~ 2300nm, infrared chalcogenide glass fiber during described super continuous spectrums laser pumping is passive, producing wavelength is the middle infrared excess continuous spectrum laser of 2000 ~ 5500nm, through filter the super continuous spectrums laser filter of wavelength less than 4500nm fallen, the residue wavelength is the super continuous spectrums laser of 4500 ~ 5500nm, described middle infrared excess continuous spectrum laser is as seed source laser, chalcogenide glass fiber through driving source excitation doping with rare-earth ions amplifies, wavelength is that a certain mid-infrared laser power in 4500 ~ 5500nm obtains amplifying, one section passive mid and far infrared chalcogenide glass fiber of mid-infrared laser excitation after the amplification, producing wavelength is the mid and far infrared super continuous spectrums laser of 5 ~ 14 μ m.
Further, described mid and far infrared optical fiber laser with super continuous spectrum also comprises amplifying stage, and the pulse laser that pulse optical fiber sends is the super continuous spectrums laser of 1000 ~ 2300nm by quartzy photonic crystal fiber generation wave-length coverage again after entering amplifying stage.
Further, described pulse optical fiber is selected the pulse optical fiber of different cavity structures according to the wavelength of the super continuous spectrums of output and the requirement of power, and its cavity structure comprises F-P chamber, annular chamber and 8 letter lock mould annular chambers.
Further, the wavelength of the super continuous spectrums that described amplifying stage is exported as required and power are selected one or more levels structure for amplifying, and the gain fibre that adopts comprises doubly clad optical fiber, the erbium ytterbium co doped double clad fiber of er-doped and mixes the doubly clad optical fiber of ytterbium.
Further, the wavelength of the semiconductor laser driving source that adopts of the material decision self of the gain fibre that adopts according to self of described amplifying stage.
Further, described quartzy photonic crystal fiber and passive in the connected mode of infrared chalcogenide glass fiber be direct mechanical docking, directly welding or lens focus spatial coupling.
Further, when described passive in the zero-dispersion wavelength of material dispersion of infrared chalcogenide glass fiber during near 2300nm, consider to save cost, described passive in infrared chalcogenide glass fiber preferably adopt common single cladded fiber structure, when described passive in infrared chalcogenide glass fiber material dispersion zero-dispersion wavelength much larger than or during much smaller than 2300nm, for obtain flatness preferably wavelength be infrared excess continuous spectrum laser among 2000 ~ 5500nm, described passive in infrared chalcogenide glass fiber preferably adopt the pyramidal structure that is provided with cone section length and cone district core diameter or be the photonic crystals optical fiber structure with airport.
Further, described mid and far infrared optical fiber laser with super continuous spectrum, also comprise condenser lens, described condenser lens focuses on super continuous spectrums laser and is coupled to chalcogenide glass fiber to produce wavelength be the middle infrared excess continuous spectrum Laser output of 2000 ~ 5500nm, and described condenser lens plating is to the anti-reflection film of 1000 ~ 2300nm wavelength laser.
Further, the chalcogenide glass fiber of the doping with rare-earth ions of described fiber amplifier, its doping ion comprise that dysprosium ion, praseodymium ion, erbium ion and/or holmium ion energy level transition can produce centre wavelength at the rare earth ion of 4500nm ~ 5500nm scope mid-infrared laser.
Further, described driving source comprises semiconductor laser and fiber laser and titanium-doped sapphire laser.
Further, when mid-infrared laser centre wavelength that the zero-dispersion wavelength of the material dispersion of described passive mid and far infrared chalcogenide glass fiber produces near the energy level transition of doping with rare-earth ions, consider to save cost, described passive mid and far infrared chalcogenide glass fiber preferably adopts common single cladded fiber structure, when the zero-dispersion wavelength of the material dispersion of described passive mid and far infrared chalcogenide glass fiber much larger than or during the mid-infrared laser centre wavelength that produces much smaller than the energy level transition of doping with rare-earth ions, for obtain flatness preferably wavelength be 5 ~ 14 μ m mid and far infrared super continuous spectrums laser, described passive mid and far infrared chalcogenide glass fiber preferably adopts the pyramidal structure that is provided with cone section length and cone district core diameter or is the photonic crystals optical fiber structure with airport.
To sum up, use infrared excess continuous laser in the generation of super continuous laser source cascade excitation chalcogenide glass fiber in the scheme described in the utility model, a kind of mid and far infrared optical fiber laser with super continuous spectrum has been proposed, by multi-stage cascade excitation and add fiber amplifier can output high-power, for the one-level driving source, adopt and common mix ytterbium, er-doped or erbium-ytterbium co-doped fiber and can realize low cost high powered Laser output as the gain fibre of first driving source amplifier; Infrared excess continuous spectrum laser produced more long wavelength's laser as driving source again during utilization produced; For the secondary driving source, the chalcogenide glass fiber that adds the doping with rare-earth ions of driving source excitation can amplify the laser of a certain wavelength in the scope of 4500 ~ 5500nm, driving source can have Mutiple Choice: fiber laser, titanium-doped sapphire laser excitation chalcogenide glass, more preferably adopt commercial semiconductor laser, can realize thus more high-power mid and far infrared Laser output.
Encourage for one-level simultaneously: adopt three kinds of coupled modes realize quartzy photonic crystal fiber and passive in the coupling of infrared chalcogenide glass fiber: if quartzy photonic crystal fiber and passive in infrared chalcogenide glass fiber employing direct mechanical Butt-coupling mode, can reduce the welding difficulty, technique is very simple, if quartzy photonic crystal fiber and passive in infrared chalcogenide glass fiber adopt the welding mode can realize all optical fibre structure, easy to use and flexible, if quartzy photonic crystal fiber and passive between the infrared chalcogenide glass fiber one section fusing point matched fiber of welding can reduce to a certain extent splice loss, splice attenuation and improve coupling efficiency, if quartzy photonic crystal fiber and passive in infrared chalcogenide glass fiber adopt the lens space coupled modes, can realize the middle infrared excess continuous spectrum Laser output of high coupling efficiency.Encourage for secondary: the chalcogenide glass fiber of suggestion doping with rare-earth ions be connected the mid and far infrared chalcogenide glass fiber and adopt the docking of direct welding mode or direct mechanical to connect.
Description of drawings
Fig. 1 is the structural representation of a kind of mid and far infrared optical fiber laser with super continuous spectrum of embodiment 1 of the present utility model;
Fig. 2 is the structural representation of a kind of mid and far infrared optical fiber laser with super continuous spectrum of embodiment 2 of the present utility model;
Fig. 3 is the pyramidal structure schematic diagram that is provided with cone section length and cone district core diameter described in the embodiment of the present utility model;
Fig. 4 is the photonic crystals optical fiber structure schematic diagram that is provided with airport described in the embodiment of the present utility model.
Embodiment
Because the chalcogenide glass material has high index of refraction, high non-linearity characteristic, and has long long wavelength limit, greater than 12 μ m, some ternary chalcogenide glass material can be greater than 14 μ m for general chalcogenide glass material; The chalcogenide glass material also has lower phonon energy simultaneously, and the rare earth ion that mixes wherein can produce irrealizable middle infrared energy level transition in the quartz glass optical fiber.Therefore the utility model embodiment will in chalcogenide glass fiber infrared and mid and far infrared chalcogenide glass fiber and doping with rare-earth ions be used for the mid and far infrared optical fiber laser with super continuous spectrum, to realize more high power and more long wavelength's Laser output.Below in conjunction with the drawings and specific embodiments the utility model is described in further detail.
Embodiment 1:
As shown in Figure 1, a kind of schematic diagram of mid and far infrared optical fiber laser with super continuous spectrum, specifically comprise pulse optical fiber 1, quartzy photonic crystal fiber 3, passive in chalcogenide glass fiber 7 and the passive mid and far infrared chalcogenide glass fiber 8 of infrared chalcogenide glass fiber 4, filter 5, driving source 6, doping with rare-earth ions.
Wherein, driving source 6 can be used fiber laser, titanium-doped sapphire laser and semiconductor laser in actual applications, for realizing effect, can adopt fiber laser and titanium-doped sapphire laser at present, but long-range see with semiconductor laser even more ideal.
In the present embodiment, certain repetition rate that pulse optical fiber 1 sends, wavelength, the laser of pulsewidth, through quartzy photonic crystal fiber 3, produce near the super continuous spectrums Laser output of wave-length coverage near-infrared, super continuous spectrums laser produces the longer middle infrared excess continuous spectrum Laser output of wavelength through infrared chalcogenide glass fiber 4 in passive, middle infrared excess continuous spectrum laser falls the super continuous spectrums laser filter of wavelength less than 4500nm through filter 5, the residue wavelength is the super continuous spectrums laser of 4500 ~ 5500nm, infrared excess continuous spectrum laser is as seed source laser in this, chalcogenide glass fiber 7 through driving source 6 excitation doping with rare-earth ions amplifies, mid-infrared laser after the amplification is as driving source, encourage one section passive mid and far infrared chalcogenide glass fiber 8, producing wavelength is the mid and far infrared super continuous spectrums laser of 5 ~ 14 μ m.
In the present embodiment, quartzy photonic crystal fiber 3 with passive in infrared chalcogenide glass fiber 4 can adopt direct mechanical to dock or the direct connected mode of welding.
More specifically, for this connected mode of direct welding, can quartzy photonic crystal fiber 3 and passive in one section fusing point matched fiber of welding between the infrared chalcogenide glass fiber 4, to reduce the fusing point loss and to improve coupling efficiency.
Preferably, when the zero-dispersion wavelength of the material dispersion of infrared chalcogenide glass fiber 4 is near 2300nm in passive, consider to save cost, infrared chalcogenide glass fiber 4 is common single cladded fiber structure in passive, in passive the zero-dispersion wavelength of the material dispersion of infrared chalcogenide glass fiber 4 much larger than or during much smaller than 2300nm, for obtain flatness preferably wavelength be infrared excess continuous spectrum laser among 2000 ~ 5500nm, passive in the structure of infrared chalcogenide glass fiber 4 for as shown in Figure 3 the pyramidal structure that is provided with cone section length and cone district core diameter or be as shown in Figure 4 the photonic crystals optical fiber structure with airport.
Preferably, when mid-infrared laser centre wavelength that the zero-dispersion wavelength of the material dispersion of passive mid and far infrared chalcogenide glass fiber 8 produces near the energy level transition of doping with rare-earth ions, consider to save cost, the common single cladded fiber structure of passive mid and far infrared chalcogenide glass fiber 8 preferred employings, when the zero-dispersion wavelength of the material dispersion of passive mid and far infrared chalcogenide glass fiber 8 much larger than or during the mid-infrared laser centre wavelength that produces much smaller than the energy level transition of doping with rare-earth ions, for obtain flatness preferably wavelength be 5 ~ 14 μ m mid and far infrared super continuous spectrums laser, the structure of passive mid and far infrared chalcogenide glass fiber 8 is for as shown in Figure 3 the pyramidal structure that is provided with cone section length and cone district core diameter or be as shown in Figure 4 the photonic crystals optical fiber structure that is provided with airport.
More specifically, the wave-length coverage of the super continuous spectrums laser that quartzy photonic crystal fiber 3 produces is 1000 ~ 2300nm, and the wavelength of middle infrared excess continuous spectrum is 2000 ~ 5500nm, and the wavelength of mid and far infrared super continuous spectrums is 5 ~ 14 μ m; The printing opacity cut-off wavelength of infrared chalcogenide glass fiber is more than or equal to 8 μ m in passive, and the printing opacity cut-off wavelength of passive mid and far infrared chalcogenide glass fiber is more than or equal to 14 μ m.
Further specify, the pulse laser that pulse optical fiber sends, producing wave-length coverage by quartzy photonic crystal fiber is the super continuous spectrums laser of 1000 ~ 2300nm, described super continuous spectrums laser is as driving source, encourage passive in infrared chalcogenide glass fiber, producing wavelength is the middle infrared excess continuous spectrum laser of 2000 ~ 5500nm, through filter the super continuous spectrums laser filter of wavelength less than 4500nm fallen, the residue wavelength is the super continuous spectrums laser of 4500 ~ 5500nm, described middle infrared excess continuous spectrum laser is as seed source laser, chalcogenide glass fiber through doping with rare-earth ions amplifies, wavelength is that the mid-infrared laser power of the predetermined wavelength in 4500 ~ 5500nm scope obtains amplifying, mid-infrared laser after the amplification is as driving source, encourage one section passive mid and far infrared chalcogenide glass fiber, producing wavelength is the mid and far infrared super continuous spectrums laser of 5 ~ 14 μ m.
Described mid and far infrared optical fiber laser with super continuous spectrum also comprises amplifying stage 2, and the pulse laser that pulse optical fiber sends is the super continuous spectrums laser of 1000 ~ 2300nm by quartzy photonic crystal fiber generation wave-length coverage again after entering amplifying stage 2.
Described pulse optical fiber is selected the pulse optical fiber of different cavity structures according to the wavelength of the super continuous spectrums of output and the requirement of power, and its cavity structure comprises F-P chamber, annular chamber and 8 letter lock mould annular chambers.Wavelength and the power of the super continuous spectrums that described amplifying stage 2 is exported are as required selected one or more levels structure for amplifying, and the gain fibre that adopts comprises doubly clad optical fiber, the erbium ytterbium co doped double clad fiber of er-doped and mixes the doubly clad optical fiber of ytterbium.The wavelength of the semiconductor laser driving source that the material decision of the gain fibre that described amplifying stage adopts according to self adopts self.
Wherein, the connected mode of the chalcogenide glass fiber 7 of doping with rare-earth ions and passive mid and far infrared chalcogenide glass fiber 8 is direct welding or mechanical splice mode.
Wherein, the chalcogenide glass fiber of doping with rare-earth ions, its doping ion comprises that the energy level transitions such as dysprosium ion, praseodymium ion, erbium ion, holmium ion can produce centre wavelength at the rare earth ion of the mid-infrared laser of 4500 ~ 5500nm scope.And the driving source of fiber amplifier has different wavelength according to the difference of its doping with rare-earth ions.
Embodiment 2:
As shown in Figure 2, a kind of mid and far infrared optical fiber laser with super continuous spectrum comprise pulse optical fiber 1, amplifying stage 2, quartzy photonic crystal fiber 3, passive in the chalcogenide glass fiber 7 of infrared chalcogenide glass fiber 4, filter 5, driving source 6, doping with rare-earth ions and passive mid and far infrared chalcogenide glass fiber 8 and condenser lens 9 form.
In the present embodiment, certain repetition rate that pulse optical fiber 1 sends, wavelength, the laser of pulsewidth obtains amplifying through amplifying stage 2 power, power is through the quartzy photonic crystal fiber 3 of laser process after amplifying, producing wave-length coverage is the super continuous spectrums output of 1000 ~ 2300nm, super continuous spectrums laser focuses on through condenser lens 9 and is coupled in passive infrared chalcogenide glass fiber 4 to produce wavelength be the middle infrared excess continuous spectrum Laser output of 2000 ~ 5500nm, middle infrared excess continuous spectrum laser falls the super continuous spectrums laser filter of wavelength less than 4500nm through filter 5, the residue wavelength is the super continuous spectrums laser of 4500 ~ 5500nm, infrared excess continuous spectrum laser is as seed source laser in this, sulphur through driving source 6 excitation doping with rare-earth ions is what remark additionally, in the accompanying drawing, 1, pulse optical fiber, 2, amplifying stage, 3, quartzy photonic crystal fiber, 4, infrared chalcogenide glass fiber in passive, 5, filter, 6, driving source, 7, the chalcogenide glass fiber of doping with rare-earth ions, 8, passive mid and far infrared chalcogenide glass fiber, 9, condenser lens.
In this programme, pulse optical fiber 1 is selected the pulse optical fiber of different cavity structures according to the wavelength of the super continuous spectrums of output and the requirement of power, and its cavity structure comprises F-P chamber, annular chamber and 8 letter lock mould annular chambers.
Simultaneously, wavelength and the power of the super continuous spectrums that amplifying stage 2 is exported are as required selected one or more levels structure for amplifying, and the gain fibre that adopts comprises doubly clad optical fiber, the erbium ytterbium co doped double clad fiber of er-doped and mixes the doubly clad optical fiber of ytterbium.
Concrete, the gain fibre that amplifying stage 2 adopts according to self is different, and the semiconductor laser driving source wavelength that amplifying stage 2 adopts according to self is also different.
Wherein, quartzy photonic crystal fiber 3 and passive in the connected mode of infrared chalcogenide glass fiber 4 be the lens focus spatial coupling.More specifically, described in passive infrared chalcogenide glass fiber 4 for common single cladded fiber or for as shown in Figure 3 the pyramidal structure that is provided with cone section length and cone district core diameter or be as shown in Figure 4 the photonic crystals optical fiber structure that is provided with airport.
Wherein, the connected mode of the chalcogenide glass fiber 7 of doping with rare-earth ions and passive mid and far infrared chalcogenide glass fiber 8 is direct welding or mechanical splice mode.More specifically, described passive mid and far infrared chalcogenide glass fiber 8 is for common single cladded fiber or for as shown in Figure 3 the pyramidal structure that is provided with cone section length and cone district core diameter or be as shown in Figure 4 the photonic crystals optical fiber structure that is provided with airport.
Simultaneously, condenser lens 9 can plate the anti-reflection film of 1000 ~ 2300nm wavelength laser to improve coupling efficiency.
Utilize at present MOPA structured optical fiber laser (pulse optical fiber 1 and amplifying stage 2) and quartzy photonic crystal fiber can realize producing the near infrared band super continuous spectrums laser of high power (tens watts to several hectowatts), the mid and far infrared optical fiber laser with super continuous spectrum of the super continuum source excitation that the utility model provides, utilize this high power near infrared band super continuous spectrums laser can realize the super continuous spectrums laser of high-power middle-infrared band as infrared chalcogenide glass fiber in the driving source excitation, utilize the thought of cascade excitation, recycle the super continuous spectrums laser of this middle-infrared band as driving source excitation mid and far infrared chalcogenide glass fiber, produce the longer mid and far infrared super continuous spectrums laser of wavelength, on this basis, utilize the laser of a certain centre wavelength of chalcogenide glass fiber centering infrared excess continuous spectrum laser of the doping with rare-earth ions of driving source excitation to carry out power amplification, to realize high power mid and far infrared Laser output.In addition, adopted in the light path that the utility model provides condenser lens in the coupling efficiency of infrared optical fiber laser with super continuous spectrum far above the coupling efficiency of infrared optical fiber laser with super continuous spectrum in the existing full optical fiber, have very large practicality.
More than infrared optical fiber laser with super continuous spectrum in the super continuum source provided by the utility model excitation is described in detail, used specific case herein principle of the present utility model and execution mode are set forth, the explanation of above embodiment just is used for helping to understand method of the present utility model and core concept thereof; Simultaneously, for one of ordinary skill in the art, according to thought of the present utility model, all will change in specific embodiments and applications, in sum, this description should not be construed as restriction of the present utility model.
Claims (9)
1. mid and far infrared optical fiber laser with super continuous spectrum, it is characterized in that, comprise pulse optical fiber, quartzy photonic crystal fiber, infrared chalcogenide glass fiber in passive, passive mid and far infrared chalcogenide glass fiber, filter, driving source and chalcogenide glass fiber, described driving source is used for the excitation chalcogenide glass fiber, wherein, the pulse laser that pulse optical fiber sends, producing wave-length coverage by quartzy photonic crystal fiber is the super continuous spectrums laser of 1000~2300nm, infrared chalcogenide glass fiber during described super continuous spectrums laser pumping is passive, producing wavelength is the middle infrared excess continuous spectrum laser of 2000~5500nm, through filter the super continuous spectrums laser filter of wavelength less than 4500nm fallen, the residue wavelength is the super continuous spectrums laser of 4500~5500nm, described middle infrared excess continuous spectrum laser is as seed source laser, amplify through driving source excitation chalcogenide glass fiber, wavelength is that the mid-infrared laser power with a certain centre wavelength in 4500~5500nm obtains amplifying, one section passive mid and far infrared chalcogenide glass fiber of mid-infrared laser excitation after the amplification, producing wavelength is the mid and far infrared super continuous spectrums laser of 5~14 μ m.
2. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1, it is characterized in that, also comprise amplifying stage, the pulse laser that pulse optical fiber sends is the super continuous spectrums laser of 1000~2300nm by quartzy photonic crystal fiber generation wave-length coverage again after entering amplifying stage.
3. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1; it is characterized in that; described pulse optical fiber is according to the wavelength of the super continuous spectrums of output and the requirement of power; select the pulse optical fiber of different cavity structures, its cavity structure comprises F-P chamber, annular chamber and 8 letter lock mould annular chambers.
4. mid and far infrared optical fiber laser with super continuous spectrum according to claim 2, it is characterized in that, the wavelength of the super continuous spectrums that described amplifying stage is exported as required and power, select one or more levels structure for amplifying, and, the wavelength of the semiconductor laser driving source that the material decision of the gain fibre that amplifying stage adopts according to self adopts self.
5. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1 is characterized in that, described driving source comprises semiconductor laser and fiber laser.
6. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1, it is characterized in that, described quartzy photonic crystal fiber and passive in the connected mode of infrared chalcogenide glass fiber be direct mechanical docking, directly welding or lens focus spatial coupling.
7. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1, it is characterized in that, passive in infrared chalcogenide glass fiber be single covering monomode fiber or be provided with the cone section length and the pyramidal structure of cone district's core diameter or be the photonic crystals optical fiber structure with airport.
8. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1, it is characterized in that, also comprise condenser lens, described condenser lens focuses on super continuous spectrums laser and is coupled to chalcogenide glass fiber to produce wavelength be the middle infrared excess continuous spectrum Laser output of 2000~5500nm, and described condenser lens plating is to the anti-reflection film of 1000~2300nm wavelength laser.
9. mid and far infrared optical fiber laser with super continuous spectrum according to claim 1, it is characterized in that passive mid and far infrared chalcogenide glass fiber is single covering monomode fiber or is provided with the cone section length with the pyramidal structure of boring district's core diameter or is the photonic crystals optical fiber structure with airport.
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| CN 201220470616 CN202957448U (en) | 2012-09-14 | 2012-09-14 | Middle and far-infrared super-continuum spectrum fiber laser |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103296569A (en) * | 2013-06-25 | 2013-09-11 | 中国人民解放军国防科学技术大学 | Super-continuum spectrum light source based on dual-band seed source Er-Yb co-doped optical fiber amplifier |
| CN107845946A (en) * | 2017-11-20 | 2018-03-27 | 北京工业大学 | A kind of all -fiber linear polarization mode-locked laser based on nonlinear optical loop mirror of cascaded pump |
| CN109406440A (en) * | 2018-11-20 | 2019-03-01 | 宁波大学 | Gas detection method based on chalcogenide glass suspention core fibre |
-
2012
- 2012-09-14 CN CN 201220470616 patent/CN202957448U/en not_active Expired - Fee Related
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103296569A (en) * | 2013-06-25 | 2013-09-11 | 中国人民解放军国防科学技术大学 | Super-continuum spectrum light source based on dual-band seed source Er-Yb co-doped optical fiber amplifier |
| CN107845946A (en) * | 2017-11-20 | 2018-03-27 | 北京工业大学 | A kind of all -fiber linear polarization mode-locked laser based on nonlinear optical loop mirror of cascaded pump |
| CN109406440A (en) * | 2018-11-20 | 2019-03-01 | 宁波大学 | Gas detection method based on chalcogenide glass suspention core fibre |
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