CN2747755Y - High power internal frequency doubling laser - Google Patents
High power internal frequency doubling laser Download PDFInfo
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- CN2747755Y CN2747755Y CN 200420075324 CN200420075324U CN2747755Y CN 2747755 Y CN2747755 Y CN 2747755Y CN 200420075324 CN200420075324 CN 200420075324 CN 200420075324 U CN200420075324 U CN 200420075324U CN 2747755 Y CN2747755 Y CN 2747755Y
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Abstract
The utility model relates to a high power internal frequency doubling laser, comprising a pumping source, an optical coupling system, a thermal-stable folding resonant cavity composed of a complete inverse mirror (1), (2), (4), and an output mirror (3), and the optical coupling system is also composed of a laser medium (5) between the complete inverse mirror (1) and the complete inverse mirror (2), and a double frequency crystal (6) between the output mirror (3) and the complete inverse mirror (4). The utility model is characterized in that the complete inverse mirror (1) is a plano-convex mirror; the complete inverse mirror (2) is a plano-concave mirror or a flat mirror; the output mirror (3) and the complete inverse mirror (4) are the plano-cancave mirrors; corresponding to the oscillating light, the plano-convex complete inverse mirror (1) and the complete inverse mirror (4) are placed through normal incidence, and the complete inverse mirror (2) and the output mirror (3) are placed through the oblique incidence. The thermal-stable cavity of the utility model can efficiently overcome the 'green light problems' of the thermal lens effect, and the frequency doubling laser with different focal distances generated by different pumping power within the large variable range; under the condition of unthreading the astigmatism compensating optical elements, the astigmatism compensation can be implemented through a larger folding angle; the utility model can remarkably increase the output power and the stability of the laser, the light-light conversion efficiency, the laser beam quality, etc.
Description
(1) technical field
The utility model belongs to laser technology field, particularly a kind of laser diode-pumped high power inner cavity frequency multiplier, it is suitable for the application in fields such as thermal imaging, laser medicine, scientific research and amusement of pumping source, light storage, laser marking, laser scribing, the printed panel of the panchromatic demonstration of laser, other laser.
(2) background technology
Watt continuous ruddiness of level, green glow, blue laser have important use in the fields such as thermal imaging, laser medicine, scientific research and amusement of the pumping source of the panchromatic demonstration of laser, other laser, light storage, laser marking, laser scribing, printed panel.Laser diode-pumped continuous inner cavity frequency-doubling laser is realized the desirable technology that has most of above-mentioned ruddiness, green glow, blue laser because of advantages such as its high power, high efficiency, high light beam quality, high stability (power and frequency), compact conformation become.At present, along with the raising of commercial laser diode laser power, the power output of laser diode-pumped in the world high power inner cavity frequency multiplier is also more and more higher.Exist for such laser, seriously influence power output and stability, the laser beam quality etc. of laser such as the thermal effect (containing thermal lensing effect, thermally induced birefringence etc.) of laser medium and frequency-doubling crystal, " green glow problem " (being double-frequency laser power instability) etc.Insert convex lens in now many employing foldings chamber and (see U.S. Patent number 5446749, its title " Diode pumped, Multi Axial Mode, IntracavityDoubled Laser "; China Patent No. ZL01225034.1, its title " the vertical pumping inner cavity frequency-doubling laser of high-power semiconductor laser "; Chinese patent application numbers 99105276.5, its title " LD pumping inner cavity frequency-doubling laser ") with high stability of optical ballast, insert λ/4 wave plates and Brewster plate or etalon (C.Czeranowsky in the folding chamber, E.Heumann, and G.Huber, All-solid-statecontinuous-wave frequency-doubled Nd:YAG-BiBO laser with 2.8W output-powerat 473nm, Optics Letters, Vol.28 (6), 432 (2003) .L.Y.Liu, M.Oka, W.Wiechmann, and S.Kubota, Longitudinally diode-pumped continuous-wave 3.5W green laser, Optical Letters, Vol.19 (3), 189 (1994)), annular chamber single-frequency operation (L.Cabaret, J.Philip, andP.Camus, Transient frequency shift in a single-mode quasi-continuousdiode-pumped Nd:YAG laser, IEEE Journal of Quantum Electronics, Vol.36 (11), 1323 (2000); M.V.Okhapkin, M.N.Skvortsov, A.M.Belkin, N.L.Kvashnin, andS.N.Bagayev, Tunable single-frequency diode-pumped Nd:YAG ring laser at1064/532nm for optical frequency standard applications, Optics Communications, 203,359 (2002)) etc. technology solves.But above-mentioned measure greatly maybe can't realize both-end pumping with the increase pump power because of optical loss, and influences the power output and the light-light conversion efficiency of laser.Particularly insert the folding chamber of Brewster plate, (such as laser medium is optical anisotropy if laser medium is because of existing birefringence, or have a thermally induced birefringence etc.) and produce complicated phase delay, add the phase delay that frequency-doubling crystal produces, the vibration polarization state of light will produce complicated variation, produce bigger optical loss when causing at every turn by the Brewster plate.Have only length to laser medium and frequency-doubling crystal etc. accurately to control or the etalon longitudinal mode selection, just the variation of above-mentioned polarization state can be overcome, and very high temperature control precision and materials processing precision will be needed the accurate control of laser medium and frequency-doubling crystal length.And modeling measure such as etalon, also must pay bigger optical loss cost.In addition, if do not insert the Brewster plate in the folding chamber, in order to realize astigmatic compensation, the folding angle in folding chamber is smaller (to be not more than 10 °, for example, China Patent No. ZL93212776.2, its title " green glow solid state laser "), if the folding angle is too small, because optical element and mounting bracket thereof can block light path, the installation of optical element etc. will be affected, and increases installation difficulty, even can't install.
(3) summary of the invention
The purpose of this utility model is just in order to solve existing thermal effect such as laser medium and frequency-doubling crystal in the above-mentioned prior art, " green glow problem ", and oscillation light and the pattern matching of pump light in the resonant cavity etc. have a strong impact on the problem of laser output power and stability, light-light conversion efficiency and beam quality, and specialized designs goes out a kind of laser diode-pumped high power inner cavity frequency multiplier newly.The plano-convex total reflective mirror that this laser utilizes the incident of Relative Oscillation light positive is as the plano-concave outgoing mirror (3) of the plano-concave of an end mirror (1) in folding chamber, an oblique incidence or average total reflective mirror (2), an oblique incidence, and the plano-concave total reflective mirror (4) of a normal incidence overcomes the thermal lensing effect of laser medium and frequency-doubling crystal effectively as the thermally-stabilised resonant cavity of another end mirror composition in folding chamber; Under the situation of not inserting any astigmatic compensation optical element, can realize astigmatic compensation with (10 °≤θ≤45 °) under the big folding angle θ, and reduce optical loss.Thereby can overcome thermal effect, " green glow problem ", optical loss etc. well influences the pattern matching between laser output power and stability, light-light conversion efficiency, zlasing mode and oscillation light (being fundamental frequency light) and pump light, laser output power and stability thereof, light-light conversion efficiency and laser beam quality have been improved greatly, make it in very big pump power scope, laser is in high-efficiency high power TEM
00Operating state.
The purpose of this utility model realizes by following scheme: this high power inner cavity frequency multiplier comprises pumping source, optical coupling system (9) and (10), by total reflective mirror (1), (2) and (4), the thermally-stabilised folding chamber that outgoing mirror (3) is formed, and be placed on the laser medium (5) between total reflective mirror (1) and (2) and be placed on outgoing mirror (3) and total reflective mirror (4) between frequency-doubling crystal (6), wherein: total reflective mirror (1) is a planoconvex lens, total reflective mirror (2) is plano-concave mirror or average mirror, and outgoing mirror (3), total reflective mirror (4) are the plano-concave mirror; Plano-convex total reflective mirror (1) is as an end mirror of thermally-stabilised folding resonant cavity, the incident of Relative Oscillation light positive is placed, total reflective mirror (4) is as another end mirror, the incident of Relative Oscillation light positive is placed, total reflective mirror (2), outgoing mirror (3) all is to tilt corresponding with respect to optical axis and is provided with, total reflective mirror (1), (2) light path between and total reflective mirror (2), folding angle θ that light path became between the outgoing mirror (3) and total reflective mirror (2), light path between the outgoing mirror (3) and outgoing mirror (3), the folding angle that light path constituted between the total reflective mirror (4) equates, guaranteeing that oscillation light is under the condition of the realization astigmatic compensation with a tight waist at frequency-doubling crystal place, consider that excessive folding angle will cause oscillation light to produce bigger polarization loss, can select 10 °≤θ≤45 °; The radius of curvature R of total reflective mirror (2)
2Radius of curvature R greater than plano-concave outgoing mirror (3)
3, by the oscillation light hot spot between total reflective mirror (1) and the total reflective mirror (2) is amplified, to guarantee that oscillation light can focus on focal beam spot radius w well at the frequency-doubling crystal place
2≤ w
1, improve shg efficiency and power; The radius of curvature R of total reflective mirror (4)
4The radius of curvature R of≤outgoing mirror (3)
3, can reduce the optical loss of resonant cavity etc.
In the utility model, the radius of curvature R of plano-convex total reflective mirror (1)
1And near the distance of laser medium end face, be according to the thermal focal length f of scope, laser medium and the frequency-doubling crystal of pump power
L1And f
L2, pump light spot radius w
p, folding angle θ, total reflective mirror (2) radius of curvature R
2, total reflective mirror (4) radius of curvature R
4, outgoing mirror (3) radius of curvature R
3, the long L in chamber between total reflective mirror (1) and (2)
1, the long L in chamber between total reflective mirror (2) and the outgoing mirror (3)
2, the long L in chamber between outgoing mirror (3) and the total reflective mirror (4)
3, minimum hot spot or the waist radius w of oscillation light on laser medium (5) and frequency-doubling crystal (6)
1With waist radius w
2Determine etc. parameter.Designing requirement is at thermal focal length f
L1And f
L2When changing significantly, resonant cavity is in steady district; Oscillation light remains unchanged substantially at the beam waist position at frequency-doubling crystal place; w
1And w
2Still can keep constant substantially; Guarantee the with a tight waist realization astigmatic compensation of oscillation light in frequency-doubling crystal simultaneously, and the oscillation light in the realization resonant cavity and the pattern matching of pump light.
Described frequency-doubling crystal (6) is placed on the oscillation light place with a tight waist between outgoing mirror (3) and the total reflective mirror (4).
The rete of each lens requires as follows: total reflective mirror (1) convex surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film, and there is the anti-reflection film of pump light on the plane at least.Total reflective mirror (2) concave surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film, and there is the anti-reflection film of pump light on the plane at least.Outgoing mirror (3) concave surface at least has corresponding fundamental frequency light to increase anti-film, the anti-reflection film of frequency doubled light.Total reflective mirror (4) concave surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film.
In the utility model, if there is the multi-stripe laser spectral line in laser medium, when the stimulated emission cross section of the spectral line that will realize laser output during less than the stimulated emission cross section of existing some spectral line, also will be to first plane of incidence of at least one chamber mirror in the folding chamber or two logical light faces plating stimulated emission cross sections anti-reflection film greater than all other spectral lines of laser output spectral line.
In the utility model, be placed on that laser medium (5) can be one between plano-convex total reflective mirror (1) and plano-concave or the average total reflective mirror (2), also can be two, the purpose of inserting two laser mediums is in order to increase pump power, avoid the damage of pump light to laser medium, reduce the thermal effect of laser medium, further improve laser output power.
The most outstanding technical characterictic of this laser have following some: (1) is by the plano-concave outgoing mirror of plano-convex total reflective mirror as the plano-concave of an end mirror in folding chamber, an oblique incidence or average total reflective mirror, an oblique incidence, and the plano-concave total reflective mirror of a normal incidence is as the thermally-stabilised resonant cavity of another end mirror composition in folding chamber, the volume that can overcome the oscillation light mode volume that the increase thermal lensing effect with pump power produced well reduces, and improves the power and the stability thereof of oscillation light.(2) optical transmission system of the plano-convex total reflective mirror (1) in the thermally-stabilised resonant cavity, plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror (3) composition, not inserting any astigmatic compensation element in the chamber avoids under the situation of polarization loss, can compensate with the astigmatism of bigger folding angle, improve frequency doubled light efficient and power output, beam quality height (TEM well oscillation light in the folding chamber
00Mould output); Guarantee that simultaneously light path is not subjected to blocking of optical element and mounting bracket thereof, is convenient to the placement of various optical elements.(3) optical transmission system of the plano-convex total reflective mirror (1) in the thermally-stabilised resonant cavity, plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror (3) composition, can overcome the oscillation light patterns of change that thermal lensing effect produced of the different different focal that pump power produced well, make the waist radius w of fundamental frequency light in frequency-doubling crystal
2Keep substantially constant, and w
2≤ w
1(oscillation light is at the minimum spot radius at laser medium place), thus shg efficiency improved.(4) optical transmission system of the plano-convex total reflective mirror (1) in the thermally-stabilised resonant cavity, plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror (3) composition, can overcome the oscillation light patterns of change that thermal lensing effect produced of the different different focal that pump power produced well, guarantee the minimum spot radius w of oscillation light on laser medium
1Basic keep constant, and realize the pump light different pump powers under and the pattern matching of oscillation light, the power output of raising laser.(5) plano-concave outgoing mirror (3) in the thermally-stabilised resonant cavity and plano-concave total reflective mirror (4) guarantee that frequency-doubling crystal is in the place with a tight waist of oscillation light, has improved shg efficiency and power output.
We adopt the utility model, the continuous Nd of the laser diode both-end pumping of being developed: YVO
4/ LBO inner cavity frequency-doubling 671nm laser, under two 808nm laser diode tail optical fiber power output sum 40W pumping, 671nm laser TEM
00Running, laser output power reaches 1.90W, and light-light conversion efficiency (laser output power/go into the pump power of laser medium) reaches 5.61%, 4 hour laser output power instability and is about 1.3% (root mean square).
The utility model operation principle is as follows:
By the end mirror of plano-convex total reflective mirror as the folding chamber, the plano-concave of an oblique incidence or average total reflective mirror, the plano-concave outgoing mirror of an oblique incidence, and the plano-concave total reflective mirror of a normal incidence is as the thermally-stabilised resonant cavity of another end mirror composition in folding chamber, wherein by plano-convex total reflective mirror (1), the optical transmission system that plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror are formed has good amplification effect to oscillation light in the folding arm at laser medium place, produce the reducing of mode volume of more serious oscillation light that thermal lensing effect is caused with compensation laser medium and frequency-doubling crystal, thereby obtain big mode volume, improve laser output power and stability thereof.
The optical transmission system of forming by plano-convex total reflective mirror (1), plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror (3), overcome the oscillation light patterns of change that thermal lensing effect produced of the different different focal that pump power produced well, guarantee oscillation light on laser medium and frequency-doubling crystal minimum hot spot or position with a tight waist and size is basic keeps constant, also improve laser output power and stability thereof.
By plano-convex total reflective mirror (1), the optical transmission system that plano-concave or average total reflective mirror (2) and plano-concave outgoing mirror (3) are formed, in the folding arm at frequency-doubling crystal place, oscillation light had good focusing effect, in the chamber, do not insert under the situation of any astigmatic compensation element, can overcome the oscillation light patterns of change that thermal lensing effect produced of the different different focal that pump power produced well, astigmatism to oscillation light under bigger folding angle compensates, thereby greatly reduced optical loss in the chamber and oscillation light polarization state variation etc., improved frequency doubled light efficient and power output well, beam quality height (TEM
00Mould output); In addition, bigger folding angle has guaranteed that also light path is not subjected to blocking of optical element and mounting bracket thereof, is convenient to the placement of various optical elements.
The radius of curvature R of plano-convex total reflective mirror (1)
1And near the distance of laser medium end face, be according to thermal lensing effect, the pump light spot radius w of scope, laser medium and the frequency-doubling crystal of pump power
p, folding angle θ, total reflective mirror (2) radius of curvature R
2, total reflective mirror (4) radius of curvature R
4, outgoing mirror (3) radius of curvature R
3, the long L in chamber between total reflective mirror (1) and (2)
1, the long L in chamber between total reflective mirror (2) and the outgoing mirror (3)
2, the long L in chamber between outgoing mirror (3) and the total reflective mirror (4)
3, the minimum spot radius w of oscillation light on laser medium (5) and frequency-doubling crystal (5)
1With waist radius w
2Etc. parameter, utilize the ABCD law of describing the Gaussian beam transmission to calculate.The condition that realizes thermally-stabilised resonant cavity is as follows:
1. resonant cavity is in steady district.
2. overcome the thermal lens focusing effect of laser medium and frequency-doubling crystal by plano-convex total reflective mirror (1) as an end mirror in folding chamber, guarantee the minimum hot spot w of oscillation light at the laser medium place
1The size substantially constant.
3. guarantee that oscillation light is constant substantially at the beam waist position at frequency-doubling crystal place, and waist radius w
2≤ w
1, require total reflective mirror (2) radius of curvature R
2Radius of curvature R greater than plano-concave outgoing mirror (3)
3, i.e. R
2>R
3
4. in order to reduce optical loss, improve resonant cavity stability, the radius of curvature R of plano-concave total reflective mirror (4)
4≤ R
3
5. under bigger folding angle situation, guarantee the with a tight waist realization astigmatic compensation of oscillation light at the frequency-doubling crystal place.
6. guarantee the pattern matching of oscillation light and pump light.
Technique scheme is suitable for the single-ended pumping of laser diode, both-end pumping, profile pump, and all kinds of inner cavity frequency-doubling lasers of flash lamp pumping.
Advantage of the present utility model is:
(1) in bigger pump power scope, the laser output power height.Utilize the laser diode-pumped continuous Nd of the utility model development: YVO
4/ LBO inner cavity frequency-doubling 671nm laser, under two 808nm laser diode tail optical fiber power output summation 40W pumping, 671nm laser TEM
00Running, laser output power reaches 1.90W.
(2) in bigger pump power scope, the light of laser-light conversion efficiency height.Utilize the laser diode-pumped continuous Nd of the utility model development: YVO
4/ LBO inner cavity frequency-doubling 671nm laser optical-light conversion efficiency reaches 5.61%.
(3) in bigger pump power scope, the output power stability height of laser.Utilize the laser diode-pumped continuous Nd of the utility model development: YVO
4/ LBO inner cavity frequency-doubling 671nm laser, during laser output power 1.90W, the laser output power instability was about 1.3% (root mean square) in 4 hours.
(4) in bigger pump power scope, the laser beam quality height.Utilize the laser diode-pumped continuous Nd of the utility model development: YVO
4/ LBO inner cavity frequency-doubling 671nm laser, during laser output power 1.90W, good beam quality, zlasing mode are TEM
00Mould.
Such laser is very suitable for the application in fields such as thermal imaging, laser medicine, scientific research and amusement of pumping source, light storage, laser marking, laser scribing, the printed panel of the panchromatic demonstration of laser, other laser.
(4) description of drawings
Fig. 1 is the light path schematic diagram of the utility model laser.
Fig. 2 inserts the light path schematic diagram of two laser mediums for the utility model laser.
Fig. 3 is the laser diode-pumped continuous Nd of the utility model development: YVO
4The power output and the pump power graph of a relation of/LBO inner cavity frequency-doubling 671nm laser.
Fig. 4 is the laser diode-pumped continuous Nd of the utility model development: YVO
4Light-the light conversion efficiency and the pump power graph of a relation of/LBO inner cavity frequency-doubling 671nm laser.
(5) embodiment
The utility model is described further below in conjunction with accompanying drawing (embodiment), but is not restriction the utility model.
As shown in Figure 1: this laser diode-pumped inner cavity frequency-doubling laser comprises pumping source (7) and (8), optical coupling system (9) and (10), by total reflective mirror (1), (2) and (4), the thermally-stabilised folding resonant cavity that outgoing mirror (3) is formed, and be placed on the laser medium (5) between total reflective mirror (1) and (2) and be placed on outgoing mirror (3) and total reflective mirror (4) between frequency-doubling crystal (6), total reflective mirror (1) is a planoconvex lens, total reflective mirror (2) is plano-concave mirror or average mirror, outgoing mirror (3) is the plano-concave mirror, and total reflective mirror (4) is the plano-concave mirror; The incident of plano-convex total reflective mirror (1) Relative Oscillation light positive is placed, the incident of total reflective mirror (4) Relative Oscillation light positive is placed, total reflective mirror (2), outgoing mirror (3) all are corresponding setting of tilting with respect to optical axis, and the light path between folding angle θ that light path became between the light path between total reflective mirror (1), (2) and total reflective mirror (2), the outgoing mirror (3) and total reflective mirror (2), the outgoing mirror (3) equates with the folding angle that light path constituted between outgoing mirror (3), the total reflective mirror (4).
Pumping source (laser diode) (7) and (8) output optical maser wavelength 808nm (U.S. Coherent company produces the FAP-Sys-30 type).The focal beam spot diameter to pump light of optical coupling system is 800 μ m, and optical coupling efficiency is 94.5%.The radius of curvature of plano-convex total reflective mirror (1) can be-100mm; Plane plating 808nm anti-reflection film, transmitance is 90%, convex surface plating 1342nm and 671nm increase anti-film, 1064nm transmitance>60%.The radius of curvature of plano-concave mirror total reflective mirror (2) is 200mm, and 10 ° of incidence angles of concave surface plating 1342nm and 671nm increase anti-film, reflectivity 99%.The radius of curvature of plano-concave outgoing mirror (3) can be 100mm; Plating 1342nm increases anti-film, reflectivity 99%; Plating 671nm anti-reflection film, transmitance 90%.Plano-concave total reflective mirror (4) radius is 100mm; Concave surface plating 1342nm and 671nm increase anti-film, reflectivity 99%.Laser medium (5) adopts Nd:YVO
4Crystal, logical light length is 12mm, doping Nd
3+Concentration 0.3%, two logical light face plating 1342nm and 808nm anti-reflection film.Frequency-doubling crystal adopts LBO, the noncritical phase matching of II class, and logical light length 12mm, two logical light are in the face of 1342nm and 671nm plating anti-reflection film.Nd:YVO
4With the side of lbo crystal all with being placed on behind the indium sheet parcel in the red copper folder, carry out temperature control with constant temperature circulator.Folding arm lengths L
1=65mm, L
2=235mm, L
3=370mm, folding angle θ=25 °.
Among Fig. 1: 7,8 is laser diode, and 9,10 is optical coupling system, and 1 is the plano-convex total reflective mirror, and 5 is laser medium, and 2 is the plano-concave total reflective mirror, and 3 is the plano-concave outgoing mirror, and 6 is lbo crystal, and 4 is the plano-concave total reflective mirror.
Fig. 2 is for inserting two laser mediums (5a) and light path schematic diagram (5b), and the purpose of inserting two laser mediums is in order to increase pump power, to avoid the damage of pump light to laser medium, reduce the thermal effect of laser medium, further improving laser output power.Requiring among other optical element and Fig. 1 is identical.
Measure laser diode-pumped continuous Nd of the present utility model: YVO with 2835-C type double-channel multifunctional laser power/energy meter that U.S. Newport produces
4The power output of/LBO inner cavity frequency-doubling 671nm laser, experimental result as shown in Figure 3.Two 808nm laser diode tail optical fiber power output sums is 40W, and promptly the pump light of 33.85W enters under the situation of laser medium, 671nm TEM
00Laser output power reaches 1.90W, and light-light conversion efficiency reaches 5.61%, sees for details shown in Figure 4.Under the 671nm laser power 1.90W situation, inner laser power output instability was about 1.3% in 4 hours.
Claims (9)
1. high power inner cavity frequency multiplier, it comprises pumping source (7) and (8), optical coupling system (9) and (10), by total reflective mirror (1), (2) and (4), the thermally-stabilised folding resonant cavity that outgoing mirror (3) is formed, and be placed on the laser medium (5) between total reflective mirror (1) and (2) and be placed on outgoing mirror (3) and total reflective mirror (4) between frequency-doubling crystal (6), it is characterized in that:
A. total reflective mirror (1) is a planoconvex lens;
B. total reflective mirror (2) is plano-concave mirror or average mirror;
C. outgoing mirror (3) is the plano-concave mirror;
D. total reflective mirror (4) is the plano-concave mirror;
E. plano-convex total reflective mirror (1) is as an end mirror of thermally-stabilised folding resonant cavity, and the incident of Relative Oscillation light positive is placed; Total reflective mirror (4) is as another end mirror, and the incident of Relative Oscillation light positive is placed; Total reflective mirror (2), outgoing mirror (3) all are to tilt corresponding with respect to optical axis and are provided with; Light path between folding angle θ that light path became between light path between total reflective mirror (1), (2) and total reflective mirror (2), the outgoing mirror (3) and total reflective mirror (2), the outgoing mirror (3) equates with the folding angle that light path constituted between outgoing mirror (3), the total reflective mirror (4), and 10 °≤θ≤45 °;
F. the radius of curvature R of total reflective mirror (2)
2Radius of curvature R greater than plano-concave outgoing mirror (3)
3, the radius of curvature R of total reflective mirror (4)
4The radius of curvature R of≤outgoing mirror (3)
3
2. high power inner cavity frequency multiplier according to claim 1 is characterized in that: the radius of curvature R of plano-convex total reflective mirror (1)
1And near the distance of laser medium end face, be according to the thermal focal length f of scope, laser medium and the frequency-doubling crystal of pump power
L1And f
L2, pump light spot radius w
p, folding angle θ, total reflective mirror (2) radius of curvature R
2, total reflective mirror (4) radius of curvature R
4, outgoing mirror (3) radius of curvature R
3, the long L in chamber between total reflective mirror (1) and (2)
1, the long L in chamber between total reflective mirror (2) and the outgoing mirror (3)
2, the long L in chamber between outgoing mirror (3) and the total reflective mirror (4)
3, minimum hot spot or the waist radius w of oscillation light on laser medium (5) and frequency-doubling crystal (5)
1And w
2Determine etc. parameter.
3. high power inner cavity frequency multiplier according to claim 1 is characterized in that: frequency-doubling crystal (6) is placed on the oscillation light place with a tight waist between outgoing mirror (3) and the total reflective mirror (4).
4. high power inner cavity frequency multiplier according to claim 1 is characterized in that: total reflective mirror (1) convex surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film, and there is the anti-reflection film of pump light on the plane at least.
5. high power inner cavity frequency multiplier according to claim 1 is characterized in that: total reflective mirror (2) concave surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film, at least the anti-reflection film of plane pump light.
6. high power inner cavity frequency multiplier according to claim 1 is characterized in that: outgoing mirror (3) concave surface at least has the anti-film of increasing of corresponding fundamental frequency light, the anti-reflection film of frequency doubled light.
7. high power inner cavity frequency multiplier according to claim 1 is characterized in that: total reflective mirror (4) concave surface at least has corresponding fundamental frequency light and frequency doubled light to increase anti-film.
8. high power inner cavity frequency multiplier according to claim 1 is characterized in that: be placed with a laser medium (5) between total reflective mirror (1) and (2).
9. high power inner cavity frequency multiplier according to claim 1 is characterized in that: be placed with two laser mediums (5a) and (5b) between total reflective mirror (1) and (2).
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 200420075324 CN2747755Y (en) | 2004-12-06 | 2004-12-06 | High power internal frequency doubling laser |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 200420075324 CN2747755Y (en) | 2004-12-06 | 2004-12-06 | High power internal frequency doubling laser |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100440648C (en) * | 2006-04-26 | 2008-12-03 | 上海致凯捷激光科技有限公司 | Wind cooled, single mold green light laser pumped at end face of semiconductor |
| CN101015474B (en) * | 2006-02-10 | 2010-08-18 | 北京瑞尔通激光科技有限公司 | Method and device for removing soft tissue of human body by using pumped high power semiconductor solid laser |
-
2004
- 2004-12-06 CN CN 200420075324 patent/CN2747755Y/en not_active Expired - Fee Related
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101015474B (en) * | 2006-02-10 | 2010-08-18 | 北京瑞尔通激光科技有限公司 | Method and device for removing soft tissue of human body by using pumped high power semiconductor solid laser |
| CN100440648C (en) * | 2006-04-26 | 2008-12-03 | 上海致凯捷激光科技有限公司 | Wind cooled, single mold green light laser pumped at end face of semiconductor |
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