CN108767648A - Saturable absorber device and preparation method thereof, mode locked fiber laser - Google Patents

Abstract

The embodiment of the invention discloses a kind of saturable absorber device and preparation method thereof, mode locked fiber lasers, wherein the saturable absorber device includes：First optical fiber；Perovskite quantum dot is attached on the end face of the first end of the first optical fiber；The first end of first Optical fiber plug, the first optical fiber is inserted into the first Optical fiber plug.Technical solution provided in an embodiment of the present invention, perovskite quantum dot is attached on the end face of the first end of the first optical fiber, the first end of the first optical fiber is inserted into the first Optical fiber plug simultaneously and forms saturable absorber device, the saturable absorber device of formation has stronger third-order nonlinear optical effect and faster response time, saturable absorber device architecture is simple simultaneously, the manufacture craft of saturable absorber device can be simplified, reduce the manufacturing cost of saturable absorber device.

Description

Saturable absorber device and preparation method thereof, mode locked fiber laser

Technical field

The present embodiments relate to field of laser device technology more particularly to a kind of saturable absorber device and its preparation sides Method, mode locked fiber laser.

Background technology

Mode locked fiber laser refers to carrying out mode locking by the way that mould-locking structure is added in the resonant cavity of optical fiber laser, in turn Generate ultrashort pulse.

Currently, mould-locking structure is broadly divided into active mode locking and passive mode-locking, passive mode-locking mainly utilizes non-thread in optical fiber Property effect, based on saturable absorber complete mode locking mechanism.Saturable absorber commonly used in the prior art has semiconductor that can satisfy With absorbing mirror SESAM, graphene and carbon nanotube CNT.

Semiconductor saturable absorbing mirror SESAM complex manufacturing technologies, it is of high cost；It is prepared by graphene and carbon nanotube CNT Journey is cumbersome, and third-order nonlinear optical effect is not strong, and the response time is slower, is unfavorable for being widely used in optical fiber laser.

Invention content

A kind of saturable absorber device of present invention offer and preparation method thereof, mode locked fiber laser, can be satisfied with simplification With the manufacture craft of absorber devices, its manufacturing cost is reduced.

In a first aspect, an embodiment of the present invention provides a kind of saturable absorber device, the saturable absorber device packet It includes：

First optical fiber；

Perovskite quantum dot is attached on the end face of the first end of the first optical fiber；

The first end of first Optical fiber plug, the first optical fiber is inserted into the first Optical fiber plug.

Optionally, saturable absorber device further includes：

The first end of second optical fiber and the second Optical fiber plug, the second optical fiber is inserted into the second Optical fiber plug；

First end optical fiber flange plate, including the first connectivity port and second connection end mouth, the first Optical fiber plug are connect with first Port connects, and the second Optical fiber plug is connect with second connection end mouth.

Optionally, it is attached with perovskite quantum dot on the end face of the first end of the second optical fiber.

Optionally, the end face of the first end of the first optical fiber is vertical with the axis of the first optical fiber.

Second aspect, the embodiment of the present invention additionally provide a kind of saturable absorber device, the saturable absorber device Including：

First glass substrate, the second glass substrate and the calcium being held between the first glass substrate and the second glass substrate Titanium ore quantum dot；

The first end of third optical fiber and third Optical fiber plug, third optical fiber is inserted into third Optical fiber plug；

The first end of 4th optical fiber and the 4th Optical fiber plug, the 4th optical fiber is inserted into the 4th Optical fiber plug；

Wherein, third Optical fiber plug is located at side of first glass substrate far from the second glass substrate, the 4th Optical fiber plug Positioned at side of second glass substrate far from the first glass substrate, third Optical fiber plug and the 4th Optical fiber plug clamp the first glass Substrate, the second glass substrate and the perovskite quantum dot being held between the first glass substrate and the second glass substrate.

Optionally, which further includes the second end optical fiber flange plate；

First glass substrate, the second glass substrate and the calcium being held between the first glass substrate and the second glass substrate Titanium ore quantum dot is located in the second end optical fiber flange plate；

Second end optical fiber flange plate includes third connectivity port and the 4th connectivity port, third Optical fiber plug and third connecting pin Mouth connection, the 4th Optical fiber plug are connect with the 4th connectivity port.

The third aspect, the embodiment of the present invention additionally provide a kind of preparation method of saturable absorber device, the preparation side Method includes：

Prepare perovskite quantum dot；

First optical fiber is provided and is attached to perovskite quantum dot on the end face of first end of the first optical fiber；

First Optical fiber plug is provided and the first end of the first optical fiber is inserted into the first Optical fiber plug.

Optionally, which further includes：

Second optical fiber and the second Optical fiber plug are provided, and the first end of the second optical fiber is inserted into the second Optical fiber plug；

There is provided the first end optical fiber flange plate, the first end optical fiber flange plate includes the first connectivity port and second connection end mouth, by the One Optical fiber plug is connect with the first connectivity port, and the second Optical fiber plug is connect with second connection end mouth.

Fourth aspect, the embodiment of the present invention additionally provide a kind of preparation method of saturable absorber device, the preparation side Method includes：

Prepare perovskite quantum dot；

First glass substrate and the second glass substrate be provided, and perovskite quantum dot is instiled in the first glass substrate and the Between two glass substrates；

Third optical fiber and third Optical fiber plug are provided, the first end of third optical fiber is inserted into third Optical fiber plug；

4th optical fiber and the 4th Optical fiber plug are provided, the first end of the 4th optical fiber is inserted into the 4th Optical fiber plug；

Third Optical fiber plug and the 4th Optical fiber plug are clamped into the first glass substrate, the second glass substrate and are held on the Perovskite quantum dot between one glass substrate and the second glass substrate.

Optionally, which further includes：

The second end optical fiber flange plate is provided, the second end optical fiber flange plate includes third connectivity port and the 4th connectivity port；

Third Optical fiber plug and the 4th Optical fiber plug are clamped into the first glass substrate, the second glass substrate and are held on the Perovskite quantum dot between one glass substrate and the second glass substrate, including：

By the first glass substrate, the second glass substrate and it is held between the first glass substrate and the second glass substrate Perovskite quantum dot is set in the second end optical fiber flange plate；

Third Optical fiber plug is connect with third connectivity port, the 4th Optical fiber plug is connect with the 4th connectivity port.

Optionally, preparing perovskite quantum dot includes：

Lead bromide and octadecylene are placed according to the first preset ratio in heating device, and by heating devices heat to first Vacuumize process is carried out after preset temperature, removes oxygen and moisture in heating device；

Oleic acid and oleyl amine are added into heating device according to the second preset ratio, while injecting indifferent gas into heating device Body ensures that the reaction in heating device carries out in atmosphere of inert gases；

The oleic acid caesium of the first preset vol will be added after heating devices heat to the second preset temperature, it is default anti-by first Heating device is subjected to cooling operation after between seasonable；

Mixture in heating device is subjected to centrifugal treating, obtains the solids in heating device；Solids is dissolved in Toluene obtains perovskite quantum dot.

5th aspect, the embodiment of the present invention additionally provide a kind of lock film optical fiber laser, which includes First pumping source and the first resonant cavity being connect with the first pumping source, the first resonant cavity include saturable absorber device, Wherein, saturable absorber device includes the first optical fiber；Perovskite quantum dot is attached to the end of the first end of first optical fiber On face；The first end of first Optical fiber plug, first optical fiber is inserted into first Optical fiber plug.

Optionally, the first resonant cavity is first annular resonant cavity, and first annular resonant cavity further includes wavelength division multiplexer, gain Optical fiber, fiber coupler and optical fiber circulator；

Wherein, the first input end of the first pumping source and wavelength division multiplexer connects, and the output end of wavelength division multiplexer passes through increasing The input terminal of beneficial optical fiber and fiber coupler connects, and the first output end of fiber coupler and the first end of optical fiber circulator connect It connects, the second output terminal of fiber coupler exports laser, and the third end of optical fiber circulator is connect with saturable absorber device, light The second end of fine circulator and the second input terminal of wavelength division multiplexer connect, and form first annular resonant cavity.

Optionally, the first resonant cavity is linear resonant cavity, and linear resonant cavity further includes wavelength division multiplexer, gain fibre, light Fine coupler and fully-reflected type bragg grating；

Wherein, the first input end of the first pumping source and wavelength division multiplexer connects, and saturable absorber device is multiple with wavelength-division It being connected with the second input terminal of device, the output end of wavelength division multiplexer is connected by the input terminal of gain fibre and fiber coupler, First output end of fiber coupler is connect with fully-reflected type bragg grating, the second output terminal output of fiber coupler Laser forms linear resonant cavity.

6th aspect, an embodiment of the present invention provides a kind of lock film optical fiber laser, which includes the Two pumping sources and the second resonant cavity being connect with the second pumping source, the second resonant cavity include saturable absorber device, In, saturable absorber device includes the first optical fiber；Perovskite quantum dot is attached to the end face of the first end of first optical fiber On；The first end of first Optical fiber plug, first optical fiber is inserted into first Optical fiber plug；Second optical fiber and the second optical fiber are inserted The first end of head, second optical fiber is inserted into second Optical fiber plug；First end optical fiber flange plate, including the first connectivity port and Second connection end mouth, first Optical fiber plug are connect with first connectivity port, second Optical fiber plug and described the Two connectivity ports connect；Alternatively, saturable absorber device is including the first glass substrate, the second glass substrate and is held on institute State the perovskite quantum dot between the first glass substrate and second glass substrate；Third optical fiber and third Optical fiber plug, institute The first end for stating third optical fiber is inserted into the third Optical fiber plug；4th optical fiber and the 4th Optical fiber plug, the 4th optical fiber First end is inserted into the 4th Optical fiber plug；Wherein, the third Optical fiber plug is located at first glass substrate far from described The side of second glass substrate, the 4th Optical fiber plug are located at second glass substrate far from first glass substrate Side, the third Optical fiber plug and the 4th Optical fiber plug clamp first glass substrate, the second glass substrate and The perovskite quantum dot being held between first glass substrate and second glass substrate.

Optionally, the second resonant cavity is the second ring resonator, and the second ring resonator further includes wavelength division multiplexer, gain Optical fiber, fibre optic isolater, connection optical fiber and fiber coupler；

Wherein, the first input end of the second pumping source and wavelength division multiplexer connects, and the output end of wavelength division multiplexer passes through increasing The input terminal of beneficial optical fiber and fibre optic isolater connects, and the output end of fibre optic isolater connects with one end of saturable absorber device It connects, the other end of saturable absorber device is connected by connecting the input terminal of optical fiber and fiber coupler, fiber coupler Second input terminal of the first output end and wavelength division multiplexer connects, and the second output terminal of fiber coupler exports laser, forms the Second ring resonant cavity.

Optionally, gain fibre includes any one in Yb dosed optical fiber, Er-doped fiber or thulium doped fiber.

Optionally, the splitting ratio of fiber coupler is R：1-R, wherein the output end export ratio of fiber coupler is R's Laser.

Saturable absorber device provided in an embodiment of the present invention and preparation method, lock film optical fiber laser, wherein can Saturated absorbing body device includes the first optical fiber；Perovskite quantum dot is attached on the end face of the first end of the first optical fiber；First light The first end of fine plug, the first optical fiber is inserted into the first Optical fiber plug.Technical solution provided in an embodiment of the present invention, by perovskite amount On the end face for the first end that son point is attached to the first optical fiber, while the first end of the first optical fiber is inserted into the first Optical fiber plug and is formed Saturable absorber device, the saturable absorber device of formation have stronger third-order nonlinear optical effect and faster Response time has reached the making work of simplified saturable absorber device simultaneously because saturable absorber device architecture is simple Skill reduces the advantageous effect of the manufacturing cost of saturable absorber device.

Description of the drawings

Fig. 1 is a kind of structural schematic diagram of saturable absorber device provided in an embodiment of the present invention；

Fig. 2 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention；

Fig. 3 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention；

Fig. 4 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention；

Fig. 5 is a kind of preparation method of saturable absorber device provided in an embodiment of the present invention；

Fig. 6 is the preparation method of another saturable absorber device provided in an embodiment of the present invention；

Fig. 7 is the preparation method of another saturable absorber device provided in an embodiment of the present invention；

Fig. 8 is a kind of structural schematic diagram of mode locked fiber laser provided in an embodiment of the present invention；

Fig. 9 is the structural schematic diagram of another mode locked fiber laser provided in an embodiment of the present invention；

Figure 10 is the structural schematic diagram of another mode locked fiber laser provided in an embodiment of the present invention.

Specific implementation mode

The present invention is described in further detail with reference to the accompanying drawings and examples.It is understood that this place is retouched The specific embodiment stated is used only for explaining the present invention rather than limitation of the invention.It also should be noted that in order to just Only the parts related to the present invention are shown in description, attached drawing rather than entire infrastructure.

Fig. 1 is a kind of structural schematic diagram of saturable absorber device provided in an embodiment of the present invention, and referring to Fig.1, this can Saturated absorbing body device includes：First optical fiber 110, perovskite quantum dot 120 and the first Optical fiber plug 130, wherein perovskite amount On the end face of 120 first end for being attached to the first optical fiber 110 of son point, the first end of the first optical fiber 110 is inserted into the first Optical fiber plug 130。

Wherein, first optical fiber 110 for acting as encapsulation and being attached with perovskite quantum dot 120 of the first Optical fiber plug 130 First end face avoids the damage perovskite quantum dot 120 in using saturable absorber device process.

Wherein, quantum dot is a kind of low dimensional semiconductor material of Nano grade, and generally spherical or spherical, diameter exists Between 2nm-20nm.The size of quantum dot is less than Exciton Bohr Radius, has very strong quantum confined effect so that exciton combines Can and oscillator strength increase, thus, quantum dot as saturable absorption know from experience have third-order nonlinear optical effect by force and Response time fast advantage.In the prior art, the quanta point material for making saturable absorber is usually carbon nanotube, stone The semi-conducting materials such as black alkene and molybdenum disulfide.Wherein, carbon nanotube is a kind of direct band gap monodimension nanometer material, band gap size It is determined by carbon nanotube diameter and attribute, absorbing wavelength is determined by the diameter of single-walled carbon nanotube, the carbon nanotube of different-diameter Wide non-linear absorption band can be achieved in mixing.But during preparing carbon nanotube saturable absorber, the pipe of carbon nanotube The control of diameter size is more difficult, and the wave-length coverage so as to cause its saturated absorption is difficult to be controlled, also, the tubulose of carbon nanotube Structural form is there are scattering loss, the laser output work by carbon nanotube saturable absorber for that can make laser in laser Rate and efficiency are restricted.Wherein, graphene is a kind of two-dimentional carbon nanomaterial, and graphene saturable absorber has and wavelength Unrelated saturated absorption characteristic, but it is relatively low in 1550nm wave band modulation depths.

Wherein, perovskite material refers to a series of materials for having perovskite crystal structure, and general chemical formula is available ABX₃It indicates, A is usually organic ion methylamine ion, ethamine ion, carbonamidine ion or inorganic ions；B be usually for Pb, Sn,Ge；X is usually Cl, Br, I.Compared to semi-conducting material manufacturing saturable absorber is utilized, made using perovskite material With third-order nonlinear optical effect, the stronger, response time is faster and saturable absorption bandwidth is broader excellent for saturable absorber Point.

It should be noted that perovskite quantum dot refers to perovskite material of the grain size between 1-10nm, perovskite amount The advantages of son point has both perovskite material and quantum dot, thus, make saturable compared to using semiconductor-quantum-point material Absorber, using perovskite quantum dot make saturable absorber have third-order nonlinear optical effect is stronger, the response time more Fast and wider Absorber Bandwidth advantage；Saturable absorber is made compared to using perovskite material, utilizes perovskite quantum Point make saturable absorber have the advantages that third-order nonlinear optical effect is stronger, the response time faster.

Saturable absorber device provided in an embodiment of the present invention, by regarding perovskite quantum dot as saturable absorber The saturable absorption layer of part, and its attachment is fiber end face and encapsulates, and ensures that the saturable absorber device to be formed has more Strong third-order nonlinear optical effect and faster corresponding time, improve the performance of saturable absorber device.Simultaneously originally The saturable absorber device architecture that inventive embodiments provide is simple, can simplify the manufacture craft of saturable absorber device, Reduce the manufacturing cost of saturable absorber device.

Fig. 2 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention, as shown in Fig. 2, Saturable absorber device provided in an embodiment of the present invention may include the first optical fiber 110, perovskite quantum dot 120, the first light Fine plug 130, the second optical fiber 210, the second Optical fiber plug 230 and the first end optical fiber flange plate 310.Wherein, perovskite quantum dot 120 It is attached on the end face of the first end of the first optical fiber 110, first end the first Optical fiber plug 130 of insertion of the first optical fiber 110, second The first end of optical fiber 210 is inserted into the second Optical fiber plug 230；First end optical fiber flange plate 310 includes that the first connectivity port and second connect Port is connect, the first Optical fiber plug 130 is connect with the first connectivity port, and the second Optical fiber plug 230 is connect with second connection end mouth.This Sample setting is advantageous in that the saturable absorber device with the structure can be in the incoming fiber optic laser of both ends.

Optionally, it can be attached with perovskite quantum dot on the end face of the first end of the second optical fiber 210, can not also adhered to Perovskite quantum dot, Fig. 2 are only said by taking non-cohesive perovskite quantum dot on the end face of the first end of the second optical fiber 210 as an example It is bright.As shown in Fig. 2, unattached on the end face of the first end of the second optical fiber 210 have perovskite quantum dot, then saturable absorber Thickness is the thickness of perovskite quantum dot on the end face of the first end of the first optical fiber 110.If it is understood that the second optical fiber Perovskite quantum dot is attached on the end face of 210 first end, then the thickness of saturable absorber is the first of the first optical fiber 110 On the end face at end on the end face of the first end of the thickness of perovskite quantum dot and the second optical fiber 210 perovskite quantum dot thickness it With.

Optionally, the end face of the first end of the first optical fiber 110 can be vertical with the axis of the first optical fiber 110, i.e. the first light The end face of the first end of fibre 110 is the fiber end face with 90 ° of corner cuts, the advantages of this arrangement are as follows, light can be from the first light Fine 110 vertical incidence are to perovskite quantum dot 120, to reduce light loss, so that using the saturable absorber device Optical fiber laser have preferable mode locking effect.

Fig. 3 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention.It, should with reference to Fig. 3 Saturable absorber device includes：First glass substrate 410, the second glass substrate 420, perovskite quantum dot 430, third optical fiber Plug 440, the 4th Optical fiber plug 450, third optical fiber 460 and the 4th optical fiber 470.

Wherein, perovskite quantum dot 430 is held between the first glass substrate 410 and the second glass substrate 420, third light The first end of fibre 460 is inserted into third Optical fiber plug 440, and the first end of the 4th optical fiber 470 is inserted into the 4th Optical fiber plug 450, third Optical fiber plug 440 is located at side of first glass substrate 410 far from the second glass substrate 420, and the 4th Optical fiber plug 470 is located at the Side of two glass substrates 420 far from the first glass substrate 410, third Optical fiber plug 440 and the 4th Optical fiber plug 450 clamp the It one glass substrate 410, the second glass substrate 420 and is held between the first glass substrate 410 and the second glass substrate 420 Perovskite quantum dot 430.

Saturable absorber device provided in an embodiment of the present invention, by regarding perovskite quantum dot as saturable absorber The saturable absorption layer of part, and it is poured between the first glass substrate and the second glass substrate, ensures that the saturable to be formed is inhaled Acceptor device has stronger third-order nonlinear optical effect and faster corresponding time, improves saturable absorber device Performance.Saturable absorber device architecture provided in an embodiment of the present invention is simple simultaneously, can simplify saturable absorber device The manufacture craft of part reduces the manufacturing cost of saturable absorber device.

Fig. 4 is the structural schematic diagram of another saturable absorber device provided in an embodiment of the present invention.In above-mentioned implementation On the basis of example, which further includes the second end optical fiber flange plate 480.First glass substrate 410, the second glass Substrate 420 and the perovskite quantum dot 430 being held between the first glass substrate and the second glass substrate are located at the second optical fiber In ring flange 480；Second end optical fiber flange plate 480 include third connectivity port and the 4th connectivity port, third Optical fiber plug 440 with Third connectivity port connects, and the 4th Optical fiber plug 450 is connect with the 4th connectivity port.The advantages of this arrangement are as follows passing through All components of saturable absorption device shown in Fig. 4 are clamped securely to together by two end optical fiber flange plates 480, and enhancing can satisfy With the transferability and practicability for absorbing device.

Fig. 5 is a kind of preparation method of saturable absorber device provided in an embodiment of the present invention, which includes：

S110, perovskite quantum dot is prepared.

Specifically, preparing perovskite quantum dot and may include：

Lead bromide and octadecylene are placed according to the first preset ratio in heating device, and by heating devices heat to first Vacuumize process is carried out after preset temperature, removes oxygen and moisture in heating device；

Oleic acid and oleyl amine are added into heating device according to the second preset ratio, while injecting indifferent gas into heating device Body ensures that the reaction in heating device carries out in atmosphere of inert gases；

The oleic acid caesium of the first preset vol will be added after heating devices heat to the second preset temperature, it is default anti-by first Heating device is subjected to cooling operation after between seasonable；

Mixture in heating device is subjected to centrifugal treating, obtains the solids in heating device；Solids is dissolved in Toluene obtains perovskite quantum dot.

Illustratively, it is illustrated below with a kind of specific preparation process：First, by the lead bromide of 69mg and 5ml Octadecylene is placed in 25ml three-necked flasks, 100 DEG C is heated to flask using heating mantle, to the lead bromide and octadecylene in flask Carrying out vacuumize process, oxygen and moisture therein are being taken out in order to preferably remove oxygen and moisture therein to remove In vacuum process, octadecylene solution is stirred using magnet rotor, which is about 60min.Then, Inert gas (such as argon gas or nitrogen) is injected into three-necked flask to ensure that the chemical reaction occurred in flask is in inertia It is carried out in atmosphere, it at the same time, will be in 0.5ml oleic acid and 0.5ml oleyl amines injection three-necked flask.Next, flask is heated To 150-170 DEG C, after temperature stabilization, 0.5ml oleic acid caesiums are injected into flask, are carried out three-necked flask after chemical reaction 40S Ice-water bath is cooled to room temperature.And then, the octadecylene solution that perovskite quantum dot is mixed in three-necked flask is averagely dispensed into 2 In the centrifuge tube of 10ml, 1-1.5ml acetone is separately added into each centrifuge tube, if solution is added just less than 6ml in centrifuge tube Hexane is supplied 6ml, and centrifuge tube is put into centrifuge, centrifugal treating 5min, centrifugal rotational speed 10Krpm.Finally, it removes Solids in centrifuge tube is dissolved in 1ml toluene by solution in centrifuge tube, will be placed in a centrifuge at centrifugation dissolved with the toluene of solids Manage 3min, centrifugal rotational speed 4Krpm, you can obtain perovskite quantum dot solution, perovskite quantum dot solution is placed in reagent bottle Middle preservation abandons remaining insoluble solids object.

It should be noted that in the embodiment of the present invention perovskite quanta point material select be CsPbBr3, CsPbBr3 systems During standby, the proportioning of each substance plays an important roll in CsPbBr3 synthesis.Lead bromide is the source of Pb and Br, oleic acid caesium For the source of Cs, the proportionate relationship of three needs to substantially meet Cs:Pb:Br=1:1:3, since Pb and Br is carried by lead bromide For, therefore while meeting Br, Pb is inevitable excessive, can be detached from solution by way of centrifugation after CsPbBr3 synthesis Out, excessive Pb just dissolves in the solution.In addition, the volume ratio of the concentration and the two of oleic acid and oleyl amine is closed in CsPbBr3 Play an important roll in, oleic acid and oleyl amine are mainly as the surface ligand in synthesis, if its concentration is too small, perovskite can shape Bodies, so as to cause quanta point material cannot be prepared；If its concentration is too big, the perovskite quantum dot prepared can be more Remaining oleic acid and oleyl amine cladding, the characteristic for causing it to be not easy to show itself.Meanwhile the oleic acid and oleyl amine of proper ratio can be with Adjust the pH value of solution in prepared by perovskite quantum dot.In addition, the length in lead bromide and oleic acid caesium reaction time will determine to synthesize Perovskite quantum dot size.If the reaction time is short, the size of perovskite quantum dot is small；If the reaction time is long, calcium titanium The size of mine quantum dot is big.And the size of perovskite quantum dot is related to its modulation depth, modulation depth is bigger, perovskite quantum The absorptivity of point is bigger, better to the narrowing result of pulse.

S120, the first optical fiber is provided and is attached to perovskite quantum dot on the end face of first end of the first optical fiber.

It is wrapped specifically, providing the first optical fiber and being attached to perovskite quantum dot on the end face of the first end of the first optical fiber It includes：

First optical fiber is provided；

Perovskite quantum dot solution is immersed into the end face of the first end of first optical fiber；

Perovskite quantum dot solution is made annealing treatment.

Illustratively, first, it is the first optical fiber to take an optical fiber, this optical fiber, using optical fiber wire stripper by the first optical fiber The coat of wherein one end divest the length of about 30-40mm, be used in combination alcohol paper by exposed optical fiber wiped clean, will be naked The optical fiber exposed is placed on optical fiber cutter, is cut first optical fiber and is made the length remainder of the exposed part of optical fiber about 10mm, meanwhile, which has 90 ° of corner cuts, this end face is the end face of the first end of the first optical fiber.It is noticeable It is that the end face of the first end of the first optical fiber not allowed to touch other objects, it is avoided to be contaminated.Then, to the first optical fiber First end end face carry out alcohol be cleaned by ultrasonic 30S, be used in combination nitrogen to dry up, then carry out acetone be cleaned by ultrasonic 30S, nitrogen is used in combination Drying finally carries out isopropanol and is cleaned by ultrasonic 30S, nitrogen is used in combination to dry up.Next, by the first of the first optical fiber cleaned up The end face at end is immersed in perovskite quantum dot solution, is taken out after 40S, that is, completes perovskite receiving quantum dot solution being attached to first On the end face of the first end of optical fiber.Finally, the end face of the first end for the first optical fiber for being attached with perovskite quantum dot solution is existed Annealing 30min is carried out at 120 DEG C, the advantages of this arrangement are as follows, the crystallinity of perovskite quanta point material can be improved And crystal lattice orientation, and then improve the Third-order nonlinearity and response speed of perovskite quanta point material.

S130, the first Optical fiber plug is provided and the first end of the first optical fiber is inserted into the first Optical fiber plug.

The preparation method of saturable absorber device provided in an embodiment of the present invention, due to perovskite quantum dot preparation process Simply, manufacturing cost is cheap, thus, the system simple with making step using the saturable absorber device of the perovskite quantum dot Standby advantageous effect at low cost.

Fig. 6 is the preparation method of another saturable absorber device provided in an embodiment of the present invention, the preparation method packet It includes：

S210, perovskite quantum dot is prepared.

S220, the first optical fiber is provided and is attached to perovskite quantum dot on the end face of first end of the first optical fiber.

S230, the first Optical fiber plug is provided and the first end of the first optical fiber is inserted into the first Optical fiber plug, the second light is provided Fine and the second Optical fiber plug, and the first end of the second optical fiber is inserted into the second Optical fiber plug.

S240, the first end optical fiber flange plate being provided, the first end optical fiber flange plate includes the first connectivity port and second connection end mouth, First Optical fiber plug is connect with the first connectivity port, the second Optical fiber plug is connect with second connection end mouth.

The preparation method of saturable absorber device provided in an embodiment of the present invention, by by the first Optical fiber plug and second Optical fiber plug is linked together by the first end optical fiber flange plate so that two of perovskite quantum dot in saturable absorber device Side is connect with optical fiber, has been reached and has been convenient for the advantageous effect in the saturable absorber device both ends incoming fiber optic laser.

Fig. 7 is the preparation method of another saturable absorber device provided in an embodiment of the present invention, the preparation method packet It includes：

S310, perovskite quantum dot is prepared.

S320, the first glass substrate and the second glass substrate are provided, and perovskite quantum dot is instiled in the first glass base Between plate and the second glass substrate.

Illustratively, first, the first glass substrate is flat on experimental bench, is spread in its one side far from experimental bench Spacer is anchored at the spacer spread on the first glass substrate by heating, the effect for spreading spacer be Uniform thickness is formed between first glass substrate and the second glass substrate.Then, the second glass substrate is flat on experimental bench On, sealant is spread in its one side far from experimental bench, and bedding and padding can be added in sealant to enhance the resistance to compression of sealant Ability, the effect for spreading sealant are to prevent the perovskite quantum dot solution of perfusion from leaking.Then by perovskite quantum dot Solution is instilled into the sealant area defined of the second glass substrate, and the first glass substrate is scattered with to the one side of spacer There is the one side of perovskite quantum dot solution to carry out with the second glass substrate bearing vacuum abutted.Finally, by ultraviolet irradiation or add The mode of heat makes sealant harden.

It is not limited between the first glass substrate and the second glass substrate it should be noted that instiling perovskite quantum dot Formula of dripping injection method, under the premise of not influencing perovskite quantum dot performance, can also be other modes, the present embodiment to this not Make specific limit.

S330, third optical fiber and third Optical fiber plug are provided, the first end of third optical fiber is inserted into third Optical fiber plug, is carried For the 4th optical fiber and the 4th Optical fiber plug, the first end of the 4th optical fiber is inserted into the 4th Optical fiber plug.

S340, third Optical fiber plug and the 4th Optical fiber plug are clamped into the first glass substrate, the second glass substrate and folder The perovskite quantum dot being held between the first glass substrate and the second glass substrate.

It is worth noting that, third Optical fiber plug and the 4th Optical fiber plug are clamped the first glass substrate, the second glass base During plate, the third optical fiber in third Optical fiber plug to be kept to be in vertical with the first glass substrate and the second glass substrate State will keep the 4th optical fiber and the first glass substrate and the second glass substrate in the 4th Optical fiber plug to be in plumbness, To ensure when the saturable absorber device is in optical fiber laser, the light that light source is sent out is passing through the saturable absorber Loss is smaller when device.

The preparation method of saturable absorber device provided in an embodiment of the present invention, due to perovskite quantum dot preparation process Simply, manufacturing cost is cheap, thus, the system simple with making step using the saturable absorber device of the perovskite quantum dot Standby advantageous effect at low cost, also, since the two sides of the first glass substrate and the second glass substrate is all plane, it is conducive to calcium titanium Mine quantum dot solution vertical folder reduces laser and passes through the saturable absorber between third Optical fiber plug and the 4th optical fiber Loss when device.

Optionally, which can also include：

The second end optical fiber flange plate is provided, the second end optical fiber flange plate includes third connectivity port and the 4th connectivity port；

Third Optical fiber plug and the 4th Optical fiber plug are clamped into the first glass substrate, the second glass substrate and are held on the Perovskite quantum dot between one glass substrate and the second glass substrate may include：

By the first glass substrate, the second glass substrate and it is held between the first glass substrate and the second glass substrate Perovskite quantum dot is set in the second end optical fiber flange plate；Third Optical fiber plug is connect with third connectivity port, the 4th optical fiber Plug is connect with the 4th connectivity port.

All components of saturable absorption device are clamped securely to together by the second end optical fiber flange plate, enhancing can The transferability and practicability of saturated absorption device, and be conducive to perovskite quantum dot solution vertical folder and inserted in third optical fiber Between head and the 4th optical fiber.

Fig. 8 is a kind of structural schematic diagram of mode locked fiber laser provided in an embodiment of the present invention.With reference to Fig. 8, the mode locking Optical fiber laser includes the first pumping source 500 and the first resonant cavity 600 for being connect with the first pumping source 500, the first resonant cavity 600 include saturable absorber device shown in FIG. 1 of the embodiment of the present invention.

Optionally, the first resonant cavity 600 is first annular resonant cavity, and first annular resonant cavity further includes wavelength division multiplexer 611, gain fibre 612, fiber coupler 613 and optical fiber circulator 614, wherein the first pumping source 500 and wavelength division multiplexer 611 first input end connection, the input that the output end of wavelength division multiplexer 611 passes through gain fibre 612 and fiber coupler 613 End connection, the first output end of fiber coupler 613 connect with the first end of optical fiber circulator 614, and the of fiber coupler 613 Two output ends export laser, and the third end of optical fiber circulator 614 is connect with saturable absorber device 615, optical fiber circulator 614 Second end connect with the second input terminal of wavelength division multiplexer 611, form first annular resonant cavity.

Illustratively, it is 974nm semiconductor laser diodes that the first pumping source 500, which is centre wavelength, and pump light passes through wave The pumping end of division multiplexer 611 enters gain fibre 612, and the length of gain fibre 612 can be 3-5m, and gain fibre 612 can Think Yb dosed optical fiber, Er-doped fiber or thulium doped fiber.Then, fiber coupler 613, fiber coupling are reached by amplified light 613 splitting ratio of device is R:1-R, 0<R<100, wherein splitting ratio can be 10:90 or 20:80, R% light output is first annular Outside resonant cavity, the light continuation of 100%-R% is run in first annular resonant cavity.Then, the light of remaining 100%-R% passes through Optical fiber circulator 614 is one-way transmitted to perovskite quantum dot saturable absorber device 615, returns wavelength division multiplexer 611, In, optical fiber circulator 614 is for ensureing light unidirectional operation in first annular resonant cavity 610.

Fig. 9 is the structural schematic diagram of another mode locked fiber laser provided in an embodiment of the present invention.With reference to Fig. 9, the lock Mode fiber laser includes the first pumping source 500 and the first resonant cavity 600 for being connect with the first pumping source 500, the first resonance Chamber 600 includes saturable absorber device shown in FIG. 1 of the embodiment of the present invention.

Optionally, the first resonant cavity 600 is linear resonant cavity, and linear resonant cavity further includes wavelength division multiplexer 621, gain light Fibre 622, fiber coupler 623 and fully-reflected type bragg grating 624, wherein the first pumping source 500 and wavelength division multiplexer 621 first input end connection, saturable absorber device 625 are connect with the second input terminal of wavelength division multiplexer 621, and wavelength-division is multiple It is connect with the input terminal of fiber coupler 623 by gain fibre 622 with the output end of device 621, the first of fiber coupler 623 Output end is connect with fully-reflected type bragg grating 624, and the second output terminal of fiber coupler 623 exports laser, is formed Linear resonant cavity.

Illustratively, it is 974nm semiconductor laser diodes that the first pumping source 500, which is centre wavelength, and pump light passes through wave The pumping end of division multiplexer 621 enters gain fibre 622, and gain fibre can be Yb dosed optical fiber, Er-doped fiber or thulium doped fiber. Then, fiber coupler 623 is reached by amplified light, 623 splitting ratio of fiber coupler is R:1-R, 0<R<100, wherein Splitting ratio can be 10:90 or 20:Outside 80, R% light output line style resonant cavity, the light of 100%-R% is passed by single mode optical fiber Defeated arrival fully-reflected type fiber bragg grating 624, the reflected light being reflected back via fully-reflected type fiber bragg grating 624 according to It is secondary that perovskite quantum dot saturable absorber device is reached by fiber coupler 623, gain fibre 622 and wavelength division multiplexer 621 Part 625.

Figure 10 is the structural schematic diagram of another mode locked fiber laser provided in an embodiment of the present invention.Referring to Fig.1 0, it should Mode locked fiber laser includes the second pumping source 700 and the second resonant cavity 800 for being connect with the second pumping source 700, and second is humorous The chamber 800 that shakes includes saturable absorber device shown in Fig. 2 of the embodiment of the present invention, 3 or 4.Figure 10 is only with the second resonant cavity 800 Include illustrating for saturable absorber device shown in Fig. 2 of the embodiment of the present invention.

Optionally, the second resonant cavity 800 is the second ring resonator, and the second ring resonator further includes wavelength division multiplexer 811, gain fibre 812, fibre optic isolater 813, connection optical fiber 814 and fiber coupler 815, wherein the second pumping source 700 with The first input end of wavelength division multiplexer 811 connects, and the output end of wavelength division multiplexer 812 passes through gain fibre 812 and Fiber isolation The input terminal of device 813 connects, and the output end of fibre optic isolater 813 is connect with one end of saturable absorber device 816, saturable The other end of absorber devices 816 is connect by connecting optical fiber with the input terminal of fiber coupler 815, fiber coupler 815 First output end is connect with the second input terminal of wavelength division multiplexer 811, and the second output terminal of fiber coupler 815 exports laser, Form the second ring resonator.

Illustratively, it is semiconductor laser that the second pumping source 700, which is centre wavelength, and pump light passes through wavelength division multiplexer 811 pumping end enters gain fibre 812, and gain fibre 812 can be Yb dosed optical fiber, Er-doped fiber or thulium doped fiber.Then, Fibre optic isolater 813 is reached by amplified light, enters connection optical fiber 814 using saturable absorber device 816, In, connection optical fiber 814 is single mode optical fiber, and length can be 10m.Finally, fiber coupler 815, splitting ratio R are reached: 1-R, 0<R<100, wherein splitting ratio can be 10:90 or 20:80, R% laser exports outside the second ring resonator, The laser continuation of 100%-R% is run in the second ring resonator.

Wherein, if gain fibre 812 is Yb dosed optical fiber, fibre optic isolater 813 is the Gao Gong that centre wavelength is 1064nm The optical fiber of rate application is to free space optical fiber isolator；First exciton of perovskite quantum dot saturable absorber device 816 is inhaled Receipts peak is 1550nm；The core diameter for connecting optical fiber 814 is 6 μm, and outer diameter is 125 μm.The mode locked fiber laser can realize center Wavelength is the femtosecond laser output near 1064nm.

Wherein, if gain fibre 812 is Er-doped fiber, fibre optic isolater 813 is the Gao Gong that centre wavelength is 1550nm The optical fiber of rate application is to free space optical fiber isolator；First exciton of perovskite quantum dot saturable absorber device 816 is inhaled Receipts peak is 1550nm；The core diameter that connection optical fiber 814 is is 9 μm, the general single mode fiber that outer diameter is 125 μm.The modelocked fiber swashs Light device can realize that centre wavelength is the femtosecond laser output near 1550nm.

Wherein, if gain fibre 812 is thulium doped fiber, fibre optic isolater 813 is the Gao Gong that centre wavelength is 1980nm The optical fiber of rate application is to free space optical fiber isolator；First exciton of perovskite quantum dot saturable absorber device 816 is inhaled Receipts peak is 1980nm；The core diameter that connection optical fiber 814 is is 9 μm, the general single mode fiber that outer diameter is 125 μm.The modelocked fiber swashs Light device can realize that centre wavelength is the femtosecond laser output near 1980nm.

It should be noted that since perovskite material has faster response speed, thus reduce using perovskite amount The mode locking time of the mode locked fiber laser of son point saturable absorber device；Since perovskite material has than semi-conducting material Broader Absorber Bandwidth, thus expand the work of the mode locked fiber laser using perovskite quantum dot saturable absorber device Make wave band.Also, the adjusting of saturable absorber device modulation depth may be implemented by adjusting the size of perovskite quantum dot, And then realize that mode locked fiber laser exports narrower pulse.In addition, the arbitrary saturable absorber device of the embodiment of the present invention It is small, thus the volume of the mode locked fiber laser using saturable absorber device is reduced, it improves modelocked fiber and swashs The portability of light device.

Note that above are only presently preferred embodiments of the present invention and institute's application technology principle.It will be appreciated by those skilled in the art that The present invention is not limited to specific embodiments described here, can carry out for a person skilled in the art it is various it is apparent variation, It readjusts and substitutes without departing from protection scope of the present invention.Therefore, although being carried out to the present invention by above example It is described in further detail, but the present invention is not limited only to above example, without departing from the inventive concept, also May include other more equivalent embodiments, and the scope of the present invention is determined by scope of the appended claims.

Claims (18)

1. a kind of saturable absorber device, which is characterized in that including：

First optical fiber；

Perovskite quantum dot is attached on the end face of the first end of first optical fiber；

The first end of first Optical fiber plug, first optical fiber is inserted into first Optical fiber plug.

2. saturable absorber according to claim 1, which is characterized in that the saturable absorber device further includes：

The first end of second optical fiber and the second Optical fiber plug, second optical fiber is inserted into second Optical fiber plug；

First end optical fiber flange plate, including the first connectivity port and second connection end mouth, first Optical fiber plug and described first Connectivity port connects, and second Optical fiber plug is connect with the second connection end mouth.

3. saturable absorber according to claim 2, which is characterized in that on the end face of the first end of second optical fiber It is attached with perovskite quantum dot.

It is protected and absorber devices 4. according to claim 1, which is characterized in that the end of the first end of first optical fiber Face is vertical with the axis of the first optical fiber.

5. a kind of saturable absorber device, which is characterized in that including：

It first glass substrate, the second glass substrate and is held between first glass substrate and second glass substrate Perovskite quantum dot；

The first end of third optical fiber and third Optical fiber plug, the third optical fiber is inserted into the third Optical fiber plug；

The first end of 4th optical fiber and the 4th Optical fiber plug, the 4th optical fiber is inserted into the 4th Optical fiber plug；

Wherein, the third Optical fiber plug is located at side of first glass substrate far from second glass substrate, described 4th Optical fiber plug is located at side of second glass substrate far from first glass substrate, the third Optical fiber plug and 4th Optical fiber plug clamp first glass substrate, the second glass substrate and be held on first glass substrate and Perovskite quantum dot between second glass substrate.

6. saturable absorber according to claim 5, which is characterized in that further include the second end optical fiber flange plate；

It first glass substrate, the second glass substrate and is held between first glass substrate and second glass substrate Perovskite quantum dot be located in second end optical fiber flange plate；

Second end optical fiber flange plate includes third connectivity port and the 4th connectivity port, the third Optical fiber plug and described the Three connectivity ports connect, and the 4th Optical fiber plug is connect with the 4th connectivity port.

7. a kind of preparation method of saturable absorber device, is used to prepare saturable absorber device as described in claim 1 Part, which is characterized in that including：

Prepare perovskite quantum dot；

First optical fiber is provided and is attached to the perovskite quantum dot on the end face of first end of first optical fiber；

First Optical fiber plug is provided and the first end of first optical fiber is inserted into first Optical fiber plug.

8. preparation method according to claim 7, which is characterized in that further include：

Second optical fiber and the second Optical fiber plug are provided, and the first end of second optical fiber is inserted into second Optical fiber plug；

The first end optical fiber flange plate is provided, first end optical fiber flange plate includes the first connectivity port and second connection end mouth, by institute It states the first Optical fiber plug to connect with first connectivity port, second Optical fiber plug is connect with the second connection end mouth.

9. a kind of preparation method of saturable absorber device, is used to prepare saturable absorber device as claimed in claim 5 Part, which is characterized in that

Prepare perovskite quantum dot；

First glass substrate and the second glass substrate are provided, and the perovskite quantum dot is instiled in first glass substrate Between second glass substrate；

Third optical fiber and third Optical fiber plug are provided, the first end of the third optical fiber is inserted into the third Optical fiber plug；

4th optical fiber and the 4th Optical fiber plug are provided, the first end of the 4th optical fiber is inserted into the 4th Optical fiber plug；

By the third Optical fiber plug and the 4th Optical fiber plug clamp first glass substrate, the second glass substrate and The perovskite quantum dot being held between first glass substrate and second glass substrate.

10. preparation method according to claim 9, which is characterized in that further include：

The second end optical fiber flange plate is provided, second end optical fiber flange plate includes third connectivity port and the 4th connectivity port；

By the third Optical fiber plug and the 4th Optical fiber plug clamp first glass substrate, the second glass substrate and The perovskite quantum dot being held between first glass substrate and second glass substrate, including：

By first glass substrate, the second glass substrate and it is held on first glass substrate and the second glass base Perovskite quantum dot between plate is set in second end optical fiber flange plate；

The third Optical fiber plug is connect with the third connectivity port, the 4th Optical fiber plug and the 4th connecting pin Mouth connection.

11. the preparation method of the saturable absorber device according to claim 7 or 9, which is characterized in that described to prepare calcium Titanium ore quantum dot includes：

Lead bromide and octadecylene are placed according to the first preset ratio in heating device, and by the heating devices heat to first Vacuumize process is carried out after preset temperature, removes oxygen and moisture in the heating device；

Oleic acid and oleyl amine are added into the heating device according to the second preset ratio, while injecting into the heating device lazy Property gas, ensures that the reaction in the heating device carries out in atmosphere of inert gases；

The oleic acid caesium of the first preset vol will be added after the heating devices heat to the second preset temperature, it is default anti-by first The heating device is subjected to cooling operation after between seasonable；

Mixture in the heating device is subjected to centrifugal treating, obtains the solids in the heating device；

The solids is dissolved in toluene, obtains perovskite quantum dot.

12. a kind of lock film optical fiber laser, which is characterized in that connect including the first pumping source and with first pumping source First resonant cavity, first resonant cavity include saturable absorber device as described in claim 1.

13. lock film optical fiber laser according to claim 12, which is characterized in that first resonant cavity is first annular Resonant cavity, the first annular resonant cavity further include wavelength division multiplexer, gain fibre, fiber coupler and optical fiber circulator；

Wherein, first pumping source is connect with the first input end of the wavelength division multiplexer, the output of the wavelength division multiplexer End is connect by the gain fibre with the input terminal of the fiber coupler, the first output end of the fiber coupler and institute The first end connection of optical fiber circulator is stated, the second output terminal of the fiber coupler exports laser, the optical fiber circulator Third end is connect with the saturable absorber device, the second end of the optical fiber circulator and the second of the wavelength division multiplexer Input terminal connects, and forms first annular resonant cavity.

14. lock film optical fiber laser according to claim 12, which is characterized in that first resonant cavity is linear resonance Chamber, the linear resonant cavity further include wavelength division multiplexer, gain fibre, fiber coupler and fully-reflected type bragg fiber light Grid；

Wherein, first pumping source is connect with the first input end of the wavelength division multiplexer, the saturable absorber device Connect with the second input terminal of the wavelength division multiplexer, the output end of the wavelength division multiplexer by the gain fibre with it is described The input terminal of fiber coupler connects, the first output end of the fiber coupler and the fully-reflected type bragg grating The second output terminal of connection, the fiber coupler exports laser, forms linear resonant cavity.

15. a kind of lock film optical fiber laser, which is characterized in that connect including the second pumping source and with second pumping source Second resonant cavity, second resonant cavity include the saturable absorber device as described in claim 2 or 5.

16. lock film optical fiber laser according to claim 15, which is characterized in that second resonant cavity is the second annular Resonant cavity, second ring resonator further include wavelength division multiplexer, gain fibre, fibre optic isolater, connection optical fiber and optical fiber Coupler；

Wherein, second pumping source is connect with the first input end of the wavelength division multiplexer, the output of the wavelength division multiplexer End is connect by gain fibre with the input terminal of the fibre optic isolater, the output end of the fibre optic isolater and the saturable One end of absorber devices connects, and the other end of the saturable absorber device passes through the connection optical fiber and the optical fiber coupling The input terminal of clutch connects, and the first output end of the fiber coupler is connect with the second input terminal of the wavelength division multiplexer, The second output terminal of the fiber coupler exports laser, forms the second ring resonator.

17. locking film optical fiber laser according to claim 13,14 and 16 any one of them, which is characterized in that the gain Optical fiber includes any one in Yb dosed optical fiber, Er-doped fiber or thulium doped fiber.

18. locking film optical fiber laser according to claim 13,14 and 16 any one of them, which is characterized in that the optical fiber The splitting ratio of coupler is R：1-R, wherein the output end export ratio of the fiber coupler is the laser of R.