CN203871646U - Pulse width tunable passive mode locking laser - Google Patents
Pulse width tunable passive mode locking laser Download PDFInfo
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- CN203871646U CN203871646U CN201420043753.6U CN201420043753U CN203871646U CN 203871646 U CN203871646 U CN 203871646U CN 201420043753 U CN201420043753 U CN 201420043753U CN 203871646 U CN203871646 U CN 203871646U
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Abstract
The utility model discloses a pulse width tunable passive mode locking laser. The laser comprises an 880nm pump source. The 880nm pump source is coupled with a pumping light coupling system through a pumping light transmission cable. The pump light coupling system is coupled with a double color lens. The double color lens is separately coupled with a gain crystal and a plane recessed reflector set. The gain crystal, a chamber length adjuster and the plane output lens are successively coupled with each other. The plane recessed reflector set is coupled with a semiconductor saturable absorber. A resonant chamber of the laser is formed by the elements disposed between the plane output lens and the semiconductor saturable absorber. The chamber length adjuster comprises two prisms. The distance adjustment between the two prisms enables continuous adjustment of the length of the resonant chamber. The distance between the two prisms is adjusted to easily adjust the length of the resonance chamber, so that the laser output pulse width is continuously adjusted and laser of different pulse width is achieved. The problem that in the prior art, continuous tunable mode locking laser with pulse width less than 1000ps fails to be output is overcome.
Description
Technical field
The utility model relates to laser technology field, particularly relates to a kind of pulse-width tunable laser with active-passive lock mould.
Background technology
All solid state picosecond laser has extensive and important application in scientific research, medicine and laser micro/nano processing and other fields, as nonlinear frequency conversion, bio-photon, laser ranging and Laser Micro-Machining etc.Different use field needs different locked mode psec pulsewidths, and the pulse duration needing as " cold working " is less than 15ps, and for regenerative amplification obtains the macro-energy green glow of kHz, the pulse duration that laser ranging needs can be loosened to 30ps etc.Therefore, development pulse-width tunable laser with active-passive lock mould becomes the focus of current research.
The high repetition frequency light pulse that laser with active-passive lock mould produces has extremely narrow pulse duration (10
-10-10
-15second), and individual pulse quite stable, can be used as regenerative amplifier and the stable seed source of psec amplifier.Because the recovery time of semiconductor saturable absorber is certain, output pulse width changes very little, can endovenous laser pattern be modulated by insert the etalon of different-thickness in resonant cavity, finally having obtained average power is 7.3W, pulse repetition frequency is 108MHz, pulsewidth scope is at the Laser output of 34ps to 1ns, and the tuning range of pulse is wide, but pulsewidth of every change, just different etalons need to be inserted, continuous precision tuning can not be realized.
And pulsewidth is greater than the output of 90ps, can export by simpler resonant cavity.For pulsewidth, be greater than the pulsewidth of 200ps, can directly modulate output by Cr4+ bonding crystal or diode.So, can be between 10ps~100ps continuous tuning, it is the difficult point of current research, the people such as the Lin Hua of Shanghai precision optical machinery research institute of the Chinese Academy of Sciences adopt by controlling the different pumping ratios of two crystal, can realize the meticulous continuous tuning of pulsewidth, realized the minimum pulse width output of 8.8ps and the maximum pulse width output of 20.3ps, but tuning range be less, and have two crystal and two pumping sources, cost is higher.
From above-mentioned, realize the continuously adjustable output that pulse duration is less than 100ps, guarantee again simple in structurely, be to be badly in need of at present the technical barrier that solves.
Utility model content
The utility model provides a kind of pulse-width tunable laser with active-passive lock mould, cannot output pulse width be less than the problem of the continuously adjustable mode-locked laser of 100ps in order to solve prior art.
For solving the problems of the technologies described above, the utility model provides a kind of pulse-width tunable laser with active-passive lock mould, comprising:
880nm pumping source, pump light Transmission Fibers, pump light coupled system, dichroic mirror, gain crystal, the long adjuster in chamber, flat output mirror, plano-concave speculum group, semiconductor saturable absorber;
Described 880nm pumping source is coupled to described pump light coupled system by described pump light Transmission Fibers, described pump light coupled system and the coupling of described dichroic mirror, described dichroic mirror is coupled with described gain crystal and described plano-concave speculum group respectively, described gain crystal, the long adjuster in described chamber and flat output mirror are coupled successively, described plano-concave speculum group and the coupling of described semiconductor saturable absorber;
Wherein, the assembly between described flat output mirror and described semiconductor saturable absorber forms the resonant cavity of laser jointly; The long adjuster in described chamber is comprised of two prisms, by regulating the distance of described two prisms to realize, regulates continuously the chamber of described resonant cavity long.
Further, the material of the prism of the long adjuster in described chamber is vitreous silica, and the triangle edges of the prism of close described flat output mirror side is grown up in the triangle length of side of another prism.
Further, described dichroic mirror is 30 ° of plane mirrors, for transmission pump light, and reflection laser.
Further, described flat output mirror is the outgoing mirror that is 5%~15% to laser-transmitting rate.
Further, a plurality of plano-concave speculums of described plano-concave speculum group are 6 ° of total reflective mirrors.
Further, described gain crystalline material is for mixing rubidium Yttrium Orthovanadate Nd:YVO
4, or, mix ytterbium yttrium-aluminium-garnet Yb:YAG; And the cross section of described gain crystal is 2mm * 2mm to 5mm * 5mm, length is 5mm~10mm.
Further, the two anti-reflection coating modes of described gain crystal by adopting.
Further, the type of cooling of described gain crystal is cooling for conducting.
Further, the pump mode of described gain crystal is continuous pumping, and pumping current is 2A~5A.
Further, the center absorbing wavelength of described semiconductor saturable absorber is 1064nm or 1030nm.
In the long adjuster in chamber of the present utility model, be provided with two prisms, by regulating the distance of these two prisms, can regulate easily the chamber of resonant cavity long, to regulate continuously Laser output pulse duration, obtain the laser of different pulse durations, solved the problem that prior art cannot output pulse width be less than the continuously adjustable mode-locked laser of 100ps.
Accompanying drawing explanation
Fig. 1 is the structural representation of pulse-width tunable laser with active-passive lock mould in the utility model embodiment;
Fig. 2 is the structural representation of pulse-width tunable laser with active-passive lock mould in the utility model preferred embodiment;
Fig. 3 is the structural representation of the long adjuster of the utility model preferred embodiment lumen;
Fig. 4 exports compared with the schematic diagram of narrow pulse waveform in the utility model preferred embodiment;
Fig. 5 exports compared with the schematic diagram of broad pulse waveform in the utility model preferred embodiment.
Embodiment
The problem that cannot output pulse width be less than the continuously adjustable mode-locked laser of 100ps in order to solve prior art, the utility model provides a kind of pulse-width tunable laser with active-passive lock mould, below in conjunction with accompanying drawing and embodiment, the utility model is further elaborated.Should be appreciated that specific embodiment described herein, only in order to explain the utility model, does not limit the utility model.
The utility model embodiment provides a kind of pulse-width tunable laser with active-passive lock mould, and its structural representation as shown in Figure 1, comprising:
880nm pumping source 1, pump light Transmission Fibers 2, pump light coupled system 3, dichroic mirror 4, gain crystal 5, the long adjuster 6 in chamber, flat output mirror 7, plano-concave speculum group 8, semiconductor saturable absorber 9; 880nm pumping source is coupled to pump light coupled system by pump light Transmission Fibers, pump light coupled system and dichroic mirror coupling, dichroic mirror is coupled with gain crystal and plano-concave speculum group respectively, gain crystal, the long adjuster in chamber and flat output mirror are coupled successively, plano-concave speculum group and semiconductor saturable absorber coupling;
Wherein, the assembly between flat output mirror and semiconductor saturable absorber forms the resonant cavity of laser jointly; The long adjuster in chamber is comprised of two prisms, by regulating the distance of two prisms to realize, regulates continuously the chamber of resonant cavity long.
In the long adjuster in chamber of the utility model embodiment, be provided with two prisms, by regulating the distance of these two prisms, can regulate easily the chamber of resonant cavity long, to regulate continuously Laser output pulse duration, obtain the laser of different pulse durations, solved the problem that prior art cannot output pulse width be less than the continuously adjustable mode-locked laser of 100ps.
In above-mentioned pulse-width tunable laser with active-passive lock mould, flat output mirror and semiconductor saturable absorber form laser resonant cavity, laser is by the starting of oscillation of gain crystal, by passing through again gain crystal after semiconductor saturable absorber locked mode, be equivalent to amplify again, through flat output mirror output high-power, high light beam quality mode-locked laser; By the long adjuster in chamber, regulate continuously chamber long, mode-locked laser that can output pulse width continuous variable.
In design process, 880nm pumping source provides maximum power 30W pump light, and the center absorbing wavelength of semiconductor saturable absorber is 1064nm or 1030nm.
The material of the prism of the long adjuster in chamber can be set to vitreous silica, and two blocks of leg-of-mutton vitreous silicas form, and.The triangle edges of the prism of close flat output mirror side is grown up in the triangle length of side of another prism, can also moving handle be set near on the prism of flat output mirror side, to adjust two distances between prism, realize the object that regulates chamber long.
While arranging, dichroic mirror is 30 ° of plane mirrors, for transmission pump light, and reflection laser; The outgoing mirror that flat output mirror is is 5%~15% to laser-transmitting rate; A plurality of plano-concave speculums of plano-concave speculum group are 6 ° of total reflective mirrors, can arrange according to demand 3,4 etc.While realizing, the chamber length that can regulate is as required determined the quantity of the speculum of plano-concave speculum group.
The material of gain crystal can be for mixing rubidium Yttrium Orthovanadate (Nd:YVO
4) or mix ytterbium yttrium-aluminium-garnet (Yb:YAG); And the cross section of gain crystal can be in the scope of 2mm * 2mm to 5mm * 5mm, length is 5mm~10mm; Gain crystal can also adopt two anti-reflection coating modes; The type of cooling of gain crystal can be cooling for conducting; The pump mode of gain crystal is continuous pumping, and pumping current is 2A~5A.
Preferred embodiment
If laser cavity is standing-wave cavity, each longitudinal mode will form a set of perfect standing wave in chamber so, since be that standing wave just has crest and node, when the gain of crest reaches the loss in chamber, will rest in that level, and so node place can continue increase because inverted population does not consume when pumping strengthens, until the gain of a longitudinal mode at its intensity Shi Bu center reach chamber loss (loss equates any one frequency) thus this longitudinal mode starting of oscillation.If pumping continues to strengthen, can between the crest of these two longitudinal modes, there is the crest of more other more longitudinal modes.This mechanism that makes HOMOGENEOUS BROADENING go out multilongitudianl-mode laser is exactly " spatial hole burning ".Be exactly in the standing-wave cavity laser of HOMOGENEOUS BROADENING MEDIUM in brief, the gain of a certain longitudinal mode causes other longitudinal mode starting of oscillation at inhomogeneous " hole burning " of spatial distribution.Accordingly, when gain crystal is positioned over to resonant cavity one end, the pulse duration of output mode-locked laser is narrower; In the time of in the middle of gain crystal is positioned over resonant cavity, the pulse duration of output mode-locked laser is wider.Cause the reason of this phenomenon to be, the position of gain crystal in laser cavity is different, and " hole burning effect " in corresponding resonant cavity is just different.When gain crystal is positioned at resonant cavity one end, in chamber, " hole burning effect " is the most obvious, thereby more frequency content can starting of oscillation.Such effect has been widened the spectral width of laser, thus corresponding shorter mode-locked laser pulse output.And when gain crystal is positioned in the middle of resonant cavity, in the chamber in " hole burning effect " a little less than, the frequency content of starting of oscillation is less, spectrum width is narrower, thereby corresponding wider mode-locked laser pulse is exported.
The implementation content of the utility model embodiment is exactly to make the position of laser crystal motionless, and the chamber that changes resonant cavity is long, makes laser crystal different in the position of resonant cavity, thereby realizes the continuous adjusting of output pulse width.
The present embodiment provides a kind of pulse-width tunable laser with active-passive lock mould, and its structure as shown in Figure 2, comprising:
880nm pumping source 1, provides maximum power 30W output, and 880nm pump light, is equivalent to be with inside-pumping, can effectively reduce at the intracrystalline heat of gain, is conducive to high power, high light beam quality Laser output.
Pump light Transmission Fibers 2, length 3m, homogenize and transmission pump light; Optical fiber core diameter 400 μ m, numerical aperture 0.22.Pump light coupled system 3, coupling ratio is 1:1, and high light beam quality pump light is coupled into gain crystal 5, the pump spot diameter on crystal is also 400 μ m; Dichroic mirror 4, transmission 880nm pump light, reflection 1064nm laser, towards pump light one side plating 880nm anti-reflection film (T > 99.5%), towards side plating 880nm high transmittance film (T > 99%) and a 1064nm high-reflecting film (R > 99.8%) in resonant cavity, can effectively avoid 1064nm laser to return in optical fiber, impact even burns out pumping source 880nm module.
Gain crystal 5 is Nd:YVO
4, the Absorber Bandwidth that it is larger and shorter upper level lifetime (92 μ s) are conducive to the generation of locked mode, and gain crystal 5 is of a size of 3mm * 3mm * 5mm, Nd:YVO
4crystal both ends of the surface plating 880nm anti-reflection film (T > 99.5%) and 1064nm anti-reflection film (T > 99.5%), its foreign atom mark is 0.5%, Nd:YVO
4indium platinum parcel for crystal, is positioned in the cooling red copper thermosphere of semiconductor chilling plate.The long adjuster 6 in chamber, regulates resonator long; Flat output mirror 7 is 10% to the transmitance of 1064nm; The first plano-concave speculum 8, radius of curvature is 1000mm; The second plano-concave speculum 9, radius of curvature is 5000mm; The 3rd plano-concave speculum 10, radius of curvature is 500mm, by Laser Focusing in semiconductor saturable absorber 11.
Semiconductor saturable absorber is of a size of 4mm * 4mm, and sticking on external diameter is on the copper thermosphere of 25.4mm, is conducive to the heat radiation of semiconductor saturable absorber.The passive mode locking device that semiconductor saturable absorber can be produced for German BATOP company, its modulation depth is 2.5%, saturation flux is 70 μ J/cm
2.
While not inserting the long adjuster 6 in chamber, along with the increase of pump power, when pump light surpasses photo threshold, output continuous laser; Further strengthen pump power, first output Q-switched pulse, is then continuous locking mold laser.Repetition rate is 29.06MHz, and the impulse waveform of output is stable.Now pumping light power is 20W, and Output of laser is 6W, and corresponding light light conversion efficiency is 30%.
The structural representation of the long adjuster 6 in chamber as shown in Figure 3, is comprised of two blocks of triangle vitreous silicas, and two quartzy shapes are identical, thereby guarantees that incident ray A is parallel with emergent ray B, can't make resonant cavity off resonance.Input path and emitting light path are all Brewster's angles, are conducive to the selection of polarised light.Wherein, little triangle quartz is fixed on base, the quartzy parallel placement of large triangle quartz and little triangle, on its handle, there is micrometer caliper scale, often revolve and turn around, advance or retreat 0.5mm, while turning clockwise, the quartz crystal length of inserting light path increases, thereby increase the distance between flat output mirror 7 and gain crystal 5, " hole burning effect " in chamber weakened, thereby output pulse width is increased, getable maximum pulse is 43.6ps, as shown in Figure 4.While being rotated counterclockwise, the quartz crystal length of inserting light path reduces, thereby reduces the distance between flat output mirror 7 and gain crystal 5, make in chamber " hole burning effect " obvious, thereby output pulse width is narrowed down, and getable narrow pulse width is 12.3ps, as shown in Figure 5.
When design, gain crystal 5 can be also Yb:YAG, and now pump light wavelength 1 should be chosen as 940nm, and the peak power output of pumping source should be 40W, and for avoiding the self-absorption of Yb:YAG crystal, should select length is the Yb:YAG crystal of 5mm.
The wavelength of pump light 1 can be also 808nm, and crystal 5Nd:YVO now gains
4foreign atom mark should reduce to 0.3%.
The pulse-width tunable laser with active-passive lock mould that the utility model embodiment provides, output pulse width is adjustable continuously, efficiently solve the demand of practical application to distinct pulse widths, volume and the cost of system have been reduced, only need in resonant cavity, insert the long adjuster in chamber, and resonant cavity can off resonance, exports mode-locked laser power high, degree of polarization is high, good beam quality.
Although be example object, preferred embodiment of the present utility model is disclosed, it is also possible those skilled in the art will recognize various improvement, increase and replacement, therefore, scope of the present utility model should be not limited to above-described embodiment.
Claims (10)
1. a pulse-width tunable laser with active-passive lock mould, is characterized in that, comprising:
880nm pumping source, pump light Transmission Fibers, pump light coupled system, dichroic mirror, gain crystal, the long adjuster in chamber, flat output mirror, plano-concave speculum group, semiconductor saturable absorber;
Described 880nm pumping source is coupled to described pump light coupled system by described pump light Transmission Fibers, described pump light coupled system and the coupling of described dichroic mirror, described dichroic mirror is coupled with described gain crystal and described plano-concave speculum group respectively, described gain crystal, the long adjuster in described chamber and flat output mirror are coupled successively, described plano-concave speculum group and the coupling of described semiconductor saturable absorber;
Wherein, the assembly between described flat output mirror and described semiconductor saturable absorber forms the resonant cavity of laser jointly;
The long adjuster in described chamber is comprised of two prisms, by regulating the distance of described two prisms to realize, regulates continuously the chamber of described resonant cavity long.
2. pulse-width tunable laser with active-passive lock mould as claimed in claim 1, it is characterized in that, the material of the prism of the long adjuster in described chamber is vitreous silica, and the triangle edges of the prism of close described flat output mirror side is grown up in the triangle length of side of another prism.
3. pulse-width tunable laser with active-passive lock mould as claimed in claim 1, is characterized in that,
Described dichroic mirror is 30 ° of plane mirrors, for transmission pump light, and reflection laser.
4. pulse-width tunable laser with active-passive lock mould as claimed in claim 1, is characterized in that,
The outgoing mirror that described flat output mirror is is 5%~15% to laser-transmitting rate.
5. pulse-width tunable laser with active-passive lock mould as claimed in claim 1, is characterized in that, a plurality of plano-concave speculums of described plano-concave speculum group are 6 ° of total reflective mirrors.
6. the pulse-width tunable laser with active-passive lock mould as described in any one in claim 1 to 5, is characterized in that,
Described gain crystalline material is for mixing rubidium Yttrium Orthovanadate Nd:YVO
4, or, mix ytterbium yttrium-aluminium-garnet Yb:YAG; And the cross section of described gain crystal is 2mm * 2mm to 5mm * 5mm, length is 5mm~10mm.
7. the pulse-width tunable laser with active-passive lock mould as described in any one in claim 1 to 5, is characterized in that, the two anti-reflection coating modes of described gain crystal by adopting.
8. pulse-width tunable laser with active-passive lock mould as claimed in claim 7, is characterized in that, the type of cooling of described gain crystal is cooling for conducting.
9. pulse-width tunable laser with active-passive lock mould as claimed in claim 7, is characterized in that, the pump mode of described gain crystal is continuous pumping, and pumping current is 2A~5A.
10. the pulse-width tunable laser with active-passive lock mould as described in any one in claim 1 to 5, is characterized in that, the center absorbing wavelength of described semiconductor saturable absorber is 1064nm or 1030nm.
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| CN201420043753.6U CN203871646U (en) | 2014-01-23 | 2014-01-23 | Pulse width tunable passive mode locking laser |
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| CN201420043753.6U CN203871646U (en) | 2014-01-23 | 2014-01-23 | Pulse width tunable passive mode locking laser |
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103794977A (en) * | 2014-01-23 | 2014-05-14 | 中国电子科技集团公司第十一研究所 | Passive mode-locking laser with tunable pulse width |
| CN104466647A (en) * | 2014-12-19 | 2015-03-25 | 深圳大学 | Topological insulator saturable absorption mirror and manufacturing method thereof |
| CN108173110A (en) * | 2018-02-01 | 2018-06-15 | 长春新产业光电技术有限公司 | Hundred hertz hundred nanosecond intensity laser device |
| CN109361143A (en) * | 2018-12-10 | 2019-02-19 | 南开大学 | The continuously adjustable passive Q regulation pulse optical fiber laser of pulsewidth based on two selenizing platinum |
| TWI700870B (en) * | 2019-06-24 | 2020-08-01 | 泓陽科技股份有限公司 | Apparatus and method of high power nanosecond mode-locked solid state laser |
-
2014
- 2014-01-23 CN CN201420043753.6U patent/CN203871646U/en not_active Expired - Lifetime
Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103794977A (en) * | 2014-01-23 | 2014-05-14 | 中国电子科技集团公司第十一研究所 | Passive mode-locking laser with tunable pulse width |
| CN104466647A (en) * | 2014-12-19 | 2015-03-25 | 深圳大学 | Topological insulator saturable absorption mirror and manufacturing method thereof |
| CN104466647B (en) * | 2014-12-19 | 2018-04-24 | 深圳大学 | Topological insulator saturable absorbing mirror and preparation method thereof |
| CN108173110A (en) * | 2018-02-01 | 2018-06-15 | 长春新产业光电技术有限公司 | Hundred hertz hundred nanosecond intensity laser device |
| CN108173110B (en) * | 2018-02-01 | 2024-01-09 | 长春新产业光电技术有限公司 | Hundred hertz and hundred nanoseconds high-energy laser |
| CN109361143A (en) * | 2018-12-10 | 2019-02-19 | 南开大学 | The continuously adjustable passive Q regulation pulse optical fiber laser of pulsewidth based on two selenizing platinum |
| TWI700870B (en) * | 2019-06-24 | 2020-08-01 | 泓陽科技股份有限公司 | Apparatus and method of high power nanosecond mode-locked solid state laser |
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