CN202260107U - Passive mode-locking ultrashort pulse all-fiber laser with waveband of 2.0 microns - Google Patents

Abstract

The utility model relates to a passive mode-locking ultrashort pulse all-fiber laser with waveband of 2.0 microns, belonging to the fields of laser technology and non-linear optics, mainly comprising a laser pumping source, a pumping beam combiner, a thulium doped or thulium-holmium co-doped rare earth doped fiber, a circulator, a saturable absorber, a laser beam splitter, an isolator, a fiber grating and a polarization controller. The passive mode-locking ultrashort pulse all-fiber laser with waveband of 2.0 microns makes use of the thulium doped or thulium-holmium co-doped rare earth doped fiber as a gain medium, and the saturable absorber as a passive mode-locking device to achieve a 2.0 microns waveband, high pulse energy and ultrashort laser pulse output. The passive mode-locking ultrashort pulse all-fiber laser with waveband of 2.0 microns employs an all-fiber structure design, and has advantages of simple structure, good environment stability and so on, and can achieve industrialization applications easily.

Description

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers

Technical field

The utility model relates to a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers, belongs to laser technology and non-linear optical field.

Background technology

Mix thulium or thulium holmium co-doped fiber laser and can launch the laser of 2.0 micron wavebands, also can realize the broad tuning of 1.7～2.1 micron waveband spectral regions, in addition, also can realize the laser output of its all band through last conversion regime.Because the laser of 2.0 micron wavebands output is in the human eye safe waveband scope; And hydrone has very strong middle infrared absorption peak, so 2.0 micron wavebands are mixed thulium or thulium holmium co-doped fiber laser has important application prospects in fields such as eye-safe, laser surgey, laser radar, ultrafast optics.In addition; 2.5～5.0 microns and 8.0～12.0 micron wavebands are two windows in the propagation in atmosphere; The laser of this wave band is of crucial importance on military applications such as laser radar, electrooptical countermeasures and laser communications; So high power 2.0 micron wavebands are mixed thulium or thulium holmium co-doped fiber laser can be used as the pumping source of optical parametric oscillator (OPO), thereby produce the laser output in 2.5～12.0 micron waveband scopes.At present; External seminar has realized the continuous thulium-doped fiber laser of 2.0 micron wavebands of kilowatt magnitude; And the domestic research that also has several family units to carry out 2.0 micron waveband thulium-doped fiber lasers; But the research work of the overwhelming majority all concentrates on the research of the continuous thulium-doped fiber laser of traditional space structure, and laser system complex structure, environmental stability be poor, limited it in some extensive applications.And the passive mode locking ultrashort pulse of all optical fibre structure, high impulse energy output is mixed the research of the fiber laser that thulium or thulium holmium mix altogether and is not also seen any report.

The utility model content

The utility model provides a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers; Utilization is mixed rare-earth doped optical fibre that thulium or thulium holmium mix altogether as gain media; Saturable absorber has been realized 2.0 micron waveband high impulse energy ultrashort laser pulses output as the passive mode locking device.This utility model adopts full fiberize structural design, environmental stability good, is easy to realize commercial application.

To achieve these goals, the utility model has been taked following technical scheme.

Mainly comprise laser pumping source, pump combiner, mix rare earth doped fiber that thulium or thulium holmium mix altogether, circulator, saturable absorber, laser beam splitter device, isolator, fiber grating, Polarization Controller etc.

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers, laser pumping source connects the pumping input of pump combiner; The common port of pump combiner connects rare-earth doped optical fibre; The other end of rare-earth doped optical fibre connects the input of circulator, and the saturable absorber of reflective structure is positioned at the position of circulator common port; The output of circulator connects the laser beam splitter device; The laser beam splitter device has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road links to each other with the signal end of pump combiner.Laser pumping source, pump combiner, rare-earth doped optical fibre, circulator, saturable absorber, laser beam splitter device be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together.

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers, laser pumping source connects the pumping input of pump combiner; The common port of pump combiner connects rare-earth doped optical fibre; The other end of rare-earth doped optical fibre connects isolator; Be provided with the saturable absorber of transmission-type structure between the input of the other end of isolator and laser beam splitter device; The laser beam splitter device has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road is connected with the signal end of pump combiner.Laser pumping source, pump combiner, rare-earth doped optical fibre, isolator, saturable absorber, laser beam splitter device be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together.Described isolator is a polarization independent type.

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers, laser pumping source connects the pumping input of pump combiner; The common port of pump combiner connects fiber grating; The other end of fiber grating connects rare-earth doped optical fibre; The other end of rare-earth doped optical fibre and the saturable absorber of reflective structure directly are coupled; The signal end of pump combiner is as the output of locked mode ultrashort laser pulse.Laser pumping source, pump combiner, fiber grating, rare-earth doped optical fibre, saturable absorber constitute 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of linear cavity structure together.The catoptrical centre wavelength of described fiber grating is λ; Reflectivity is R, wherein: 1700nm＜λ＜2100nm; 1%＜R＜99%.

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers, laser pumping source connects the pumping input of pump combiner; The common port of pump combiner connects rare-earth doped optical fibre; The other end of rare-earth doped optical fibre connects the laser beam splitter device; The laser beam splitter device has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road links to each other with an end of Polarization Controller; The other end of Polarization Controller connects isolator, and the other end of isolator links to each other with Polarization Controller; The other end of Polarization Controller connects the signal end of pump combiner.Laser pumping source, pump combiner, rare-earth doped optical fibre, laser beam splitter device, Polarization Controller, isolator, Polarization Controller be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together.Described isolator is the polarization relationship type.

Above-mentioned laser pumping source is semiconductor laser, fiber laser or Raman laser, and wherein: the centre wavelength of semiconductor laser output laser is between 700～900nm; The centre wavelength of fiber laser or Raman laser output laser is between 1400～1600nm.

Above-mentioned rare-earth doped optical fibre is monomode fiber or big core diameter multimode fiber or photonic crystal fiber, and its doped rare earth element is that thulium or thulium holmium are mixed altogether.

Above-mentioned saturable absorber can be semiconductor saturable absorbing mirror (SESAM), CNT (SWNT), Graphene (Graphene) etc.

Above-mentioned pump combiner, rare-earth doped optical fibre, circulator, laser beam splitter device, isolator, fiber grating are for protecting bias tyre or non-guarantor's bias tyre.

2.0 microns above-mentioned passive mode locking ultrashort pulse full-optical-fiber lasers directly use or use as the seed source of fiber amplifier.

The splitting ratio of above-mentioned laser beam splitter device is: T: (1-T), and 0＜T＜1 wherein.

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of the utility model have the following advantages:

The full fiberize structural design that the utility model adopts makes whole laser system have advantages such as simple in structure, that light-phototranstormation efficiency is high, environmental stability is good, the output pulse energy is big, is easy to realize the industrial sector application.

Description of drawings

Fig. 1 is the theory structure sketch map of embodiment 1.

Fig. 2 is the passive mode locking pulse train of embodiment 1.

Fig. 3 is the passive mode locking spectrogram of embodiment 1.

Fig. 4 is the theory structure sketch map of embodiment 2.

Fig. 5 is the theory structure sketch map of embodiment 3.

Fig. 6 is the theory structure sketch map of embodiment 4.

Among the figure: 1, laser pumping source, 2, pump combiner, 3, mix the rare earth doped fiber that thulium or thulium holmium are mixed altogether, 4, circulator, 5, saturable absorber, 6, the laser beam splitter device, 7, isolator, 8, fiber grating, 9, Polarization Controller, 10, Polarization Controller.

Embodiment

1-6 is described further the utility model below in conjunction with diagram, but is not limited only to following several kinds of embodiment.

Embodiment 1

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers adopt ring cavity structure design as shown in Figure 1.Mainly comprise: centre wavelength is that 790nm, power output are that the multiple die semiconductor laser of 6W is as laser pumping source 1; (2+1) pump combiner 2 of x1 structure; What 10m was long mixes thulium double clad single-mode fiber 3 as gain media, and the core diameter of mixing thulium double clad single-mode fiber 3 is 6 μ m, and cladding diameter is 125 μ m; Three fiber port circulators 4; Modulation depth is the semiconductor saturable absorbing mirror (SESAM) of 30% reflective structure; 1x2 structure, splitting ratio are 30: 70 laser beam splitter device 6.Wherein: centre wavelength is 790nm, and power output is the pumping input that the multiple die semiconductor laser 1 of 6W connects (2+1) x1 pump combiner 2; (2+1) common port of x1 pump combiner 2 connects the long end of mixing thulium double clad single-mode fiber 3 of 10m; The other end of mixing thulium double clad single-mode fiber 3 connects the input of three fiber port circulators 4; Since light can only unidirectional sequence through three ports of circulator 4; Thereby light is by the input entering of optical fiber circulator 4; The light that comes out from optical fiber circulator 4 common ports is through behind the reflective semiconductor saturable absorbing mirror 5, and getting into splitting ratio is the input of 30: 70 laser beam splitter device 6; Laser beam splitter device 6 is divided into two bundles with light, and 70% light is from the output output of beam splitter 6, and other 30% light arrives the signal end of pump combiner 2.The semiconductor saturable absorbing mirror 5 of reflective structure is as the locked mode device, and the locked mode ultrashort laser pulse will be from 70% output output of laser beam splitter device 6.As shown in Figure 2, the length of whole laserresonator is about 24m, and the repetition rate of its passive mode locking laser pulse is 8.3MHz.Shown in Figure 3 is the output spectrum of passive mode locking thulium-doped fiber laser, and its centre wavelength is 2007nm, and the 3dB spectral bandwidth is 1.3nm.Because the luminous power that feeds back in the laser cavity only accounts for about 30%, laser cavity internal power density is low, a little less than the nonlinear effect, is difficult for pulsing division phenomenon, so can realize high impulse energy ultrashort laser pulse output.Adopt the cladding pumping mode also to improve the output energy of mode-locked laser pulse in addition.

Embodiment 2

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers adopt ring cavity structure design as shown in Figure 4.Mainly comprise: centre wavelength is that 1550nm, power output are that the single mode erbium doped fiber laser of 3W is as laser pumping source 1; 1550/2000nm wavelength division multiplexer (WDM) is as pump light bundling device 2; What 3m was long mixes thulium double clad single-mode fiber 3 as gain media, and the core diameter of mixing thulium double clad single-mode fiber 3 is 9 μ m, and cladding diameter is 125 μ m; Isolation is the polarization irrelevant isolator 7 of 30dB; The Graphene saturable absorber 5 of transmission-type structure; 1x2 structure, splitting ratio are 20: 80 laser beam splitter device 6.Wherein: centre wavelength is that 1550nm, power output are the pumping input of the single mode erbium doped fiber laser 1 connection wavelength division multiplexer 2 of 3W; The common port of wavelength division multiplexer 2 connect 3m long mix thulium double clad single-mode fiber 3; The other end of mixing thulium double clad single-mode fiber 3 connects the end that polarization does not have optical isolator 7; Graphene saturable absorber 5 does not have between optical isolator 7 and the laser beam splitter device 6 at polarization; Laser beam splitter device 6 is divided into two bundles with light, and 20% light is from the output output of beam splitter 6, and other 80% light feeds back to the signal end of wavelength division multiplexer 2.What 3m was long mixes thulium double clad single-mode fiber 3 as gain media, and the Graphene saturable absorber 5 of transmission-type structure is as the locked mode device, thereby realizes 2.0 microns high impulse energy ultrashort laser pulses outputs.

Embodiment 3

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers adopt linear cavity structural design as shown in Figure 5.Mainly comprise: centre wavelength is that 1550nm, power output are that the single mode erbium doped fiber laser of 3W is as laser pumping source 1; 1550/2000nm wavelength division multiplexer (WDM) is as pump light bundling device 2; Centre wavelength is that 2000nm, 3dB spectral bandwidth are that 2nm, reflectivity are 90% Fiber Bragg Grating FBG 8; What 3m was long mixes thulium double clad single-mode fiber 3 as gain media, and the core diameter of mixing thulium double clad single-mode fiber 3 is 9 μ m, and cladding diameter is 125 μ m; Modulation depth is the semiconductor saturable absorbing mirror (SESAM) 5 of 40% reflective structure.Wherein: centre wavelength is that 1550nm, power output are the pumping input of the single mode erbium doped fiber laser 1 connection wavelength division multiplexer 2 of 3W; It is an end of 90% Fiber Bragg Grating FBG 8 that the common port of wavelength division multiplexer 2 connects reflectivity; Reflectivity be the other end of 90% Bragg grating 8 connect 3m long mix thulium double clad single-mode fiber 3; Mixing the other end of thulium double clad single-mode fiber 3 and the semiconductor saturable absorbing mirror of reflective structure (SESAM) 5 directly is coupled; The signal end of 1550/2000nm wavelength division multiplexer 2 is as the output of passive mode locking ultrashort laser pulse.Reflectivity is 90% a Fiber Bragg Grating FBG 8 and the semiconductor saturable absorbing mirror (SESAM) 5 of reflective structure constitutes the linear laser resonant cavitys, thereby realizes the signal end output of 2.0 microns passive mode locking ultrashort laser pulses from wavelength division multiplexer 2.

Described fiber grating 8 catoptrical central wavelength lambda; Reflectivity is R, and its span is: 1700nm＜λ＜2100nm; 1%＜R＜99%.

Embodiment 4

A kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers adopt ring cavity structure design as shown in Figure 6.Mainly comprise: centre wavelength is that 1550nm, power output are that the single mode erbium doped fiber laser of 3W is as laser pumping source 1; 1550/2000nm wavelength division multiplexer (WDM) is as pump light bundling device 2; What 3m was long mixes thulium double clad single-mode fiber 3 as gain media, and the core diameter of mixing thulium double clad single-mode fiber 3 is 9 μ m, and cladding diameter is 125 μ m; 1x2 structure, splitting ratio are 30: 70 laser beam splitter device 6; The polarization isolator 7 of being correlated with; Polarization Controller 9 and 10.Wherein: centre wavelength is that 1550nm, power output are the pumping input of the single mode erbium doped fiber laser 1 connection wavelength division multiplexer 2 of 3W; The common port of wavelength division multiplexer 2 connect 3 meters long mix thulium double clad single-mode fiber 3; The other end of mixing thulium double clad single-mode fiber 3 connects the input of laser beam splitter device 6; Laser beam splitter device 6 is divided into two bundles with light, and 30% light is from the output output of laser beam splitter device 6, and other 70% light gets into an end of Polarization Controller 9; Between an end of the other end of Polarization Controller 9 and Polarization Controller 10, be connected with the relevant isolator 7 of polarization; The other end of Polarization Controller 10 connects the signal end of wavelength division multiplexer 2.What 3m was long mixes thulium double clad single-mode fiber 3 as gain medium; The relevant isolator 7 of polarization is formed the passive mode locking devices with Polarization Controller 9 with 10, exports from an end of 30% of laser beam splitter device 6 thereby the polarization state of suitable adjusting Polarization Controller 9 and 10 realizes 2.0 microns passive mode locking ultrashort laser pulses.

In four above-mentioned embodiment, described laser pumping source 1 is semiconductor laser, fiber laser or Raman laser, and wherein, the centre wavelength of semiconductor laser output laser can be between 700～900nm; The centre wavelength of fiber laser or Raman laser output laser can be between 1400～1600nm.

Claims (9)

1. a micron waveband passive mode locking ultrashort pulse full-optical-fiber laser is characterized in that: the pumping input of laser pumping source (1) connection pump combiner (2); The common port of pump combiner (2) connects rare-earth doped optical fibre (3); The other end of rare-earth doped optical fibre (3) connects the input of circulator (4), and the saturable absorber of reflective structure (5) is positioned at the position of circulator (4) common port; The output of circulator (4) connects laser beam splitter device (6); Laser beam splitter device (6) has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road links to each other with the signal end of pump combiner (2).Laser pumping source (1), pump combiner (2), rare-earth doped optical fibre (3), circulator (4), saturable absorber (5), laser beam splitter device (6) be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together.

2. a micron waveband passive mode locking ultrashort pulse full-optical-fiber laser is characterized in that: the pumping input of laser pumping source (1) connection pump combiner (2); The common port of pump combiner (2) connects rare-earth doped optical fibre (3); The other end of rare-earth doped optical fibre (3) connects isolator (7); Be provided with the saturable absorber (5) of transmission-type structure between the other end of isolator (7) and the input of laser beam splitter device; Laser beam splitter device (6) has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road is connected with the signal end of pump combiner (2).Laser pumping source (1), pump combiner (2), rare-earth doped optical fibre (3), isolator (7), saturable absorber (5), laser beam splitter device (6) be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together.Described isolator (7) is a polarization independent type.

3. a micron waveband passive mode locking ultrashort pulse full-optical-fiber laser is characterized in that: the pumping input of laser pumping source (1) connection pump combiner (2); The common port of pump combiner (2) connects fiber grating (8); The other end of fiber grating (8) connects rare-earth doped optical fibre (3); The saturable absorber (5) of the other end of rare-earth doped optical fibre (3) and reflective structure directly is coupled; The signal end of pump combiner (2) is as the output of locked mode ultrashort laser pulse.Laser pumping source (1), pump combiner (2), fiber grating (8), rare-earth doped optical fibre (3), saturable absorber (5) constitute 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of linear cavity structure together; The centre wavelength of described fiber grating (8) is λ; Reflectivity is R, wherein: 1700nm＜λ＜2100nm; 1%＜R＜99%.

4. a micron waveband passive mode locking ultrashort pulse full-optical-fiber laser is characterized in that: the pumping input of laser pumping source (1) connection pump combiner (2); The common port of pump combiner (2) connects rare-earth doped optical fibre (3); The other end of rare-earth doped optical fibre (3) connects laser beam splitter device (6); Laser beam splitter device (6) has two-way output, one tunnel output as the locked mode ultrashort laser pulse, and another road links to each other with an end of Polarization Controller (9); The other end of Polarization Controller (9) connects isolator (7), and the other end of isolator (7) links to each other with Polarization Controller (10); The other end of Polarization Controller (10) connects the signal end of pump combiner (2).Laser pumping source (1), pump combiner (2), rare-earth doped optical fibre (3), laser beam splitter device (6), Polarization Controller (9), isolator (7), Polarization Controller (10) be 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of looping cavity configuration together; Described isolator (7) is the polarization relationship type.

5. according to claim 1 or claim 2 or claim 3 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4; It is characterized in that: described laser pumping source (1) is semiconductor laser, fiber laser or Raman laser; Wherein, the centre wavelength of semiconductor laser output laser is between 700～900nm; The centre wavelength of fiber laser or Raman laser output laser is between 1400～1600nm.

6. according to claim 1 or claim 2 or claim 3 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4; It is characterized in that: described rare-earth doped optical fibre (3) is monomode fiber or big core diameter multimode fiber or photonic crystal fiber, and its doped rare earth element is that thulium or thulium holmium are mixed altogether.

7. according to claim 1 or claim 2 or claim 3 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4, it is characterized in that: described saturable absorber (5) is semiconductor saturable absorbing mirror (SESAM) or CNT (SWNT) or Graphene (Graphene).

8. according to claim 1 or claim 2 or claim 3 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4, it is characterized in that: described pump combiner (2), rare-earth doped optical fibre (3), circulator (4), laser beam splitter device (6), isolator (7), fiber grating (8) are for protecting bias tyre or non-guarantor's bias tyre.

9. according to claim 1 or claim 2 or claim 3 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4, it is characterized in that: described 2.0 microns passive mode locking ultrashort pulse full-optical-fiber lasers directly use or use as the seed source of fiber amplifier.

10, according to claim 1 or claim 2 or the described a kind of 2.0 micron waveband passive mode locking ultrashort pulse full-optical-fiber lasers of claim 4, it is characterized in that: the splitting ratio of described laser beam splitter device (6) is: T: (1-T), and 0＜T＜1 wherein.

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