WO2018045701A1 - Spectrum regulation apparatus for mid-infrared pulse laser light - Google Patents

Abstract

A spectrum regulation apparatus for mid-infrared pulse laser light (B). In the present spectrum regulation apparatus, near-infrared pulse laser light (A) emitted by a near-infrared pulse laser (1) passes through an optical coupling lens (2) and, together with mid-infrared pulse laser light (B), enters an aperiodically poled crystal (3); by means of non-linear frequency conversion and using the near-infrared pulse laser light (A) as a pump light, differential amplification of the different spectral components of the mid-infrared pulse laser light (B) is performed, thereby implementing spectrum regulation. The spectrum regulation apparatus uses type I quasi-phase matching technology and, by means of adjusting the working temperature of the aperiodically poled crystal (3), eliminates the group velocity mismatch of the near-infrared pump light and the mid-infrared signal light in the crystal (3). The spectrum regulation apparatus is therefore suitable for femtosecond magnitude mid-infrared ultrashort pulse laser light (B) without the need for chirp broadening, as near-infrared pulse laser light (A) can be used directly to perform spectral shaping thereof, greatly simplifying the complexity of a spectrum regulation apparatus based on non-linear frequency conversion.

Description

 Spectral control device for mid-infrared pulsed laser

 Technical field

 The invention relates to the field of laser technology, in particular to a spectrum control device for a mid-infrared pulsed laser.

 Background technique

From basic research in strong field physics to medical and industrial applications, mid-infrared pulsed lasers are widely used in many different fields. However, due to the lack of suitable laser gain media and effective detection methods, commercial femtosecond lasers still use titanium gems ( Ti:sapphire) is mainly composed of solid-state lasers and erbium-doped ( Er) fiber lasers, and the laser wavelength is generally less than 2 μm.

 Based on the existing pulsed laser, pulsed laser light of any wavelength can be obtained by nonlinear frequency conversion, such as the mid-infrared band that is difficult to directly generate (3-5) μ m ). After years of development, quasi-phase matching (QPM It has become a mature technology for phase matching of nonlinear frequency conversion. By periodically changing the polarization direction of the nonlinear crystal, the energy of the pump light is continuously transferred to the signal light. Choosing the appropriate polarization period, in theory, can achieve any nonlinear frequency conversion in the range of the nonlinear crystal pass. Periodically polarized lithium niobate crystals ( PPLN is one of the most typical periodic polarization crystals and is widely used for optical frequency conversion of mid-infrared lasers. Although there are large effective nonlinear coefficients, PPLN The limited phase matching bandwidth limits its use in ultrashort pulsed lasers. In practical applications, people often need to trade off matching bandwidth and conversion efficiency. To overcome this limitation, non-periodic polarized crystals have been proposed and demonstrated to be suitable for wideband frequency conversion of ultrashort pulsed lasers. By regularly changing the polarization inversion period of the nonlinear crystal, different spectral components of the signal light can satisfy the quasi-phase matching condition in different regions of the crystal, thereby realizing wide-spectrum optical parametric amplification. In theory, a non-periodic polarized crystal can provide a gain bandwidth of any width and even shape the spectrum of the signal light. but , The premise is that during the optical parametric amplification process, the pump light, the signal light, and the idler light are substantially synchronized in time. However, in general, the group velocity of the interacting pump light, signal light, and idler light in the crystal is not the same, and is generally called group velocity mismatch. Group speed mismatch can cause laser pulse time out of sync. Among them, the separation between the pump light and the signal light may cause the signal light to not be continuously amplified, resulting in the non-periodically polarized crystal failing to complete the originally set target, such as regulating the output spectrum. In order to reduce the effects of time walk away, in the past, non-periodic polarized crystals were mainly used for helium pulsed lasers, or only very short non-periodically polarized crystals could be used. This greatly increases the complexity of nonlinear frequency conversion systems and sets insurmountable obstacles to their potential applications. especially in In the mid-infrared band of 3-5 μm, pulse broadening and compression of the ultrashort pulse laser in this spectral region is still an arduous engineering task due to the lack of effective detection means.

 The prior art has yet to be improved and improved.

 Summary of the invention

In view of the above-mentioned deficiencies of the prior art, it is an object of the present invention to provide a spectral control device for a mid-infrared pulsed laser that is suitable for a mid-infrared ultrashort pulse laser of the femtosecond order without the need for it. Broadening, you can directly use the near-infrared pulse laser to spectrally shape it.

 In order to achieve the above object, the present invention adopts the following technical solutions:

 A spectral control device for a mid-infrared pulsed laser, comprising:

 Near infrared pulsed laser;

 Optical coupling mirror

 Non-periodic polarized crystal;

 a temperature control furnace for regulating the operating temperature of the non-periodically polarized crystal;

 Beam splitter

 The near-infrared pulse laser, the optical coupling mirror, the non-periodically polarized crystal, and the beam splitter are sequentially placed;

a near-infrared pulsed laser emitted by a near-infrared pulsed laser passes through the optical coupling mirror, enters the non-periodically polarized crystal together with the mid-infrared pulsed laser, and uses a near-infrared pulsed laser as a pumping light through nonlinear frequency conversion. Differentiating the different spectral components of the mid-infrared pulsed laser; the mixed light of the non-periodically polarized crystal output A spectrally modulated mid-infrared pulsed laser is obtained after separation by the spectroscope.

 In the spectral control device for the mid-infrared pulsed laser, the non-periodically polarized crystal is satisfied. A quasi-polarized crystal that matches the quasi-position, and the polarization inversion period of the non-periodically polarized crystal changes non-periodically along the longitudinal direction.

 In the spectral control device for the mid-infrared pulsed laser, the signal light and the pump light are in the non-periodically polarized crystal The temperature at which the group velocity is the same is the operating temperature.

 In the spectral control device for the mid-infrared pulsed laser, the non-periodically polarized crystal is a non-periodically polarized lithium niobate crystal.

 In the spectral control device for the mid-infrared pulsed laser, the near-infrared pulse laser is 790 nm Ti:Sapphire femtosecond pulsed laser.

 In the spectral control device for the mid-infrared pulsed laser, the beam splitter is an optical element that can separate mixed light of different wavelengths from each other.

Compared with the prior art, the present invention provides a spectral control device for a mid-infrared pulsed laser. In the spectral control device, the near-infrared pulsed laser light emitted by the near-infrared pulse laser passes through the optical coupling mirror, enters the non-periodically polarized crystal together with the mid-infrared pulsed laser, and passes through a nonlinear frequency conversion to The infrared pulsed laser is pumping light, and the different spectral components of the mid-infrared pulsed laser are differentially amplified; the mixed light of the non-periodically polarized crystal output A spectrally modulated mid-infrared pulsed laser is obtained after separation by the spectroscope. The invention adopts class I quasi-phase matching technology to adjust the operating temperature of the non-periodically polarized crystal, Eliminating the group velocity mismatch between the near-infrared pump light and the mid-infrared signal light in the crystal; on the basis of this, the non-periodic polarization crystal is a nonlinear crystal, and the difference of the mid-infrared pulse laser by nonlinear frequency conversion The spectral components are differentially amplified to achieve regulation of their spectra. The technical solution is applicable to a mid-infrared ultrashort pulse laser of the femtosecond order, since the near-infrared pump light and the mid-infrared signal light are always kept in synchronization, so that the mid-infrared ultrashort pulse laser is not required to be widened, and the direct solution can be directly Spectral shaping using near-infrared pulsed laser greatly simplifies the complexity of spectral control devices based on nonlinear frequency conversion.

 DRAWINGS

 FIG. 1 is a schematic diagram of an optical path of a spectral control device for a mid-infrared pulsed laser provided by the present invention.

 Figure 2 shows the relationship between the wavelength of the signal light and the crystal temperature under the premise that the pump light and the signal light satisfy the group velocity matching.

 FIG. 3 is a graph showing the variation of the optical parametric gain with the pulse width of the spectral control device for the mid-infrared pulsed laser provided by the present invention.

 4 is a spectrum control device for a mid-infrared pulse laser provided by the present invention, wherein the chirp pulse width is 425fs. The pulse envelope and spectrum of the amplified mid-infrared pulsed laser.

 5 is a spectrum adjustment device for a mid-infrared pulse laser provided by the present invention, wherein the chirp pulse width is 700 fs The pulse envelope and spectrum of the amplified mid-infrared pulsed laser.

 6 is a spectrum control device for a mid-infrared pulse laser provided by the present invention, wherein the chirp pulse width is 1250fs. The pulse envelope and spectrum of the amplified mid-infrared pulsed laser.

 7 is a spectrum adjustment device for a mid-infrared pulse laser provided by the present invention, wherein a chirp pulse width is 2500 fs The pulse envelope and spectrum of the amplified mid-infrared pulsed laser.

 detailed description

The invention provides a spectroscopic control device for a mid-infrared pulsed laser. The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

 The refractive index ( n ) of the crystal changes with temperature, and the group velocity of the pulsed laser in the crystal ( v ) ) is also a physical quantity related to temperature. In order to take advantage of the nonlinear nonlinear coefficient (d33) of a nonlinear crystal, non-periodic polarized crystals usually need to satisfy the quasi-phase matching condition of class 0 (e+e- › e ), requires pump light, signal light, and idler light to be e Polarized light. The two pulsed lasers in the same polarization state have a large difference in group velocity, and this difference cannot be simply eliminated by changing the operating temperature of the non-periodically polarized crystal. However, when the two lasers propagate in the crystal in an orthogonal manner (for example, the signal light is o Polarized light, pump light is e-polarized light), they will have the same group velocity at a certain temperature. In order to eliminate the group velocity mismatch between the pump light and the signal light, the spectral control device for the mid-infrared pulse laser uses I Quasi-phase matching technology, using the dispersion relationship between the group velocity of the pulsed laser and the crystal temperature, by adjusting the operating temperature of the crystal, the signal light and the pump light satisfy the group velocity matching (GVM=0) ). In this time-synchronized operating state, in theory, even if long nonlinear crystals are used, they do not move away during the interaction. Under such physical conditions, the non-periodically polarized crystal can be directly applied to the nonlinear frequency conversion of the ultrashort pulse laser of the femtosecond level without the need to widen the width, and the spectrum is regulated.

 Further, referring to FIG. 1 , the present invention provides a spectral control device for a mid-infrared pulsed laser, including a near-infrared pulse laser 1 . An optical coupling mirror 2, a non-periodically polarized crystal 3, a temperature control furnace 4 and a beam splitter 7 for regulating the operating temperature of the non-periodically polarized crystal 3. Wherein, the signal light and the pump light are in the The temperature at which the group velocity in the non-periodically polarized crystal is the same is the operating temperature.

 The near-infrared pulse laser 1 , the optical coupling mirror 2 , the non-periodically polarized crystal 3 , and the beam splitter 7 are sequentially placed; The near-infrared pulsed laser light emitted by the near-infrared pulsed laser 1 passes through the optical coupling mirror 2 and enters the non-periodically polarized crystal together with the mid-infrared pulsed laser light 3 And differentiating the different spectral components of the mid-infrared pulsed laser by using a near-infrared pulsed laser as a pumping light by nonlinear frequency conversion; and mixing the output light of the non-periodically polarized crystal 3 through the beam splitter 7 After separation, a spectrally modulated mid-infrared pulsed laser is obtained. The near-infrared pulse laser refers to a pulsed laser having a wavelength in the range of 750 to 2000 nm.

 The invention adopts class I quasi-phase matching technology to adjust the operating temperature of the non-periodically polarized crystal, The group velocity mismatch between the near-infrared pump light and the mid-infrared signal light in the crystal is eliminated, and the different spectral components of the mid-infrared pulse laser are differentially amplified by nonlinear frequency conversion, thereby realizing the adjustment of the spectrum. Output lasers of different spectral characteristics can also be obtained by using different non-periodically polarized crystals.

 Please refer to Figure 2 and Figure 2 The variation of the signal light wavelength with the crystal temperature is given under the premise that the pump light and the signal light satisfy the group velocity matching. As can be seen from the figure, the fit 3 A commercial pulsed laser of different wavelengths, this group velocity matching scheme can be applied to the mid-infrared band of 2-5 μm. Therefore, the mid-infrared pulsed laser has a wavelength of 2-5 μm. In 3 μ m The typical mid-infrared wavelength is taken as an example, and the present invention will be further described in detail by the following examples.

 In the spectral control device shown in Figure 1, the direction of the arrow is the direction of light propagation, the near-infrared pulsed laser A and the mid-infrared pulsed laser B. After being coupled by the optical coupling mirror 2, it enters the non-periodically polarized crystal 3. The near-infrared pulsed laser light A is reflected by the optical coupling mirror 2 and enters the non-periodically polarized crystal 3. Mid-infrared pulsed laser B Through the optical coupling mirror 2, it enters the non-periodically polarized crystal 3.

 Further, the near-infrared pulse laser 3 is a 790 nm titanium gem femtosecond pulse laser, and the output wavelength thereof is 790 nm. Pulse laser A, through the optical coupling mirror 2, enters the non-periodically polarized crystal 3 together with a mid-infrared pulsed laser B having a wavelength of 3 μm, with a pulsed laser having a wavelength of 790 nm A is pump light, which amplifies the mid-infrared pulsed laser B (as signal light) with a wavelength of 3 μm, and at the same time, achieves effective regulation of its spectrum.

 The non-periodically polarized crystal 3 is a non-periodically polarized crystal that satisfies the class I alignment. The non-periodically polarized crystal 3 The polarization inversion period varies non-periodically in the longitudinal direction (ie, the direction in which the pulsed laser propagates). In this embodiment, the non-periodically polarized crystal 3 is selected from a non-periodic polarization lithium niobate crystal (APPLN). ).

 The non-periodically polarized crystal 3 The length and the non-periodically changing polarization inversion period are determined according to the spectral characteristics of the input mid-infrared pulsed laser and the desired output spectral characteristics. With this specially designed crystal, the mid-infrared pulsed laser can be ensured. Different spectral components can satisfy the quasi-phase matching conditions in different regions of the crystal, obtain amplification, and can adjust the amplification period of different spectral components of the mid-infrared pulse laser by rationally designing the polarization inversion period of the crystal, thereby realizing the mid-infrared pulse. Regulation of laser spectroscopy.

 The temperature control furnace 4 is disposed under the non-periodically polarized crystal 3; the temperature control furnace 4 is configured to the non-periodically polarized crystal 3 The operating temperature is controlled. Specifically, the temperature control furnace 4 causes the non-periodically polarized crystal 3 to operate at a set temperature, so that the signal light and the pump light are in the non-periodically polarized crystal 6. The group speed is the same.

 The beam splitter 9 is an optical element that can separate mixed light of different wavelengths from each other; preferably, It is one of a dichroic prism and a dichroic mirror. The mixed light C output from the non-periodically polarized crystal 3 is separated by the beam splitter 7 to obtain a spectrally modulated mid-infrared pulsed laser light D.

 Specifically, it is assumed that the transmission limit pulse width of the mid-infrared pulsed laser B with a wavelength of 3 μm is 100 fs. , spread it to different pulse widths. Correspondingly, the pulse width of the near-infrared pulsed laser A with a wavelength of 790 nm is consistent with that of the mid-infrared pulsed laser. In order to make the pump light with wavelength 790nm and wavelength 3 The signal light of μ m satisfies the group speed matching, and the temperature of the APPLN crystal is fixed at 127 °C (set temperature) through the crystal temperature control furnace. The length of the APPLN crystal is 10mm The polarization inversion period varies linearly from 34.06 μm to 34.24 μm. Based on HCP's 5% doped MgO: PPLN The refractive index formula of the present invention numerically simulates the operation of the spectral control device for the mid-infrared pulsed laser. In order to prove its superiority, we use APPLN that satisfies class 0 quasi-phase matching. The case was also simulated when the crystal length was 2 mm and the polarization inversion period was linearly changed from 21.76 μm to 21.7 μm. As shown in Figure 3, Figure 3 The curve of the optical parametric gain with the pulse width is given. As the width of the chirped pulse decreases, the time between laser pulses becomes more severe. When the mid-infrared pulsed laser has a chirp width greater than 2 ps, either Class I or Class 0 QPM can achieve comparable optical parametric gain. Class 0 QPM as the pulse width of the 啁啾 is gradually reduced In this case, the optical parametric gain decreases rapidly. More importantly, due to the mismatch between the pump light and the signal light group velocity, the pump light and the signal light will go to each other in time before the short-wavelength component of the signal light is amplified. The spectrum of the mid-infrared pulsed laser that is amplified is severely 'red shifted'. The pulse envelope and spectrum of the amplified mid-infrared pulsed laser at different pulse widths are listed in Figure 4-7, respectively. The solid line indicates the class I quasi-phase matching curve, and the dotted line indicates 0. The quasi-phase-matched curve clearly reveals the trend of the output spectrum as a function of the pulse width. In contrast, the spectral control device for mid-infrared pulsed lasers uses APPLN that satisfies Class I QPM. The crystal, by means of the non-periodically changing polarization inversion period, increases the spectral width of the mid-infrared pulsed laser while substantially retaining its spectral characteristics. With such a design, the spectral control device for the mid-infrared pulsed laser can be directly applied to the ultra-short pulse laser without flaw width, and the spectrum of the mid-infrared ultrashort pulse laser of the femtosecond order is adjusted to increase the bandwidth thereof. And even plastic.

 It can be seen that the spectral control device for the mid-infrared pulsed laser can use a longer APPLN. The crystal uses the dispersion relationship between the group velocity of the pulsed laser and the crystal temperature to operate the crystal at a set temperature, thereby eliminating the group velocity mismatch between the near-infrared pump light and the mid-infrared signal light in the crystal. The polarization inversion period of the non-periodically varying period is determined based on the spectral characteristics of the input mid-infrared pulsed laser and the desired output spectral characteristics. With this specially designed crystal, the different spectral components of the mid-infrared pulsed laser can satisfy the quasi-phase matching conditions in different regions of the crystal, obtain amplification, and can control the mid-infrared pulse laser by rationally designing the polarization inversion period of the crystal. The magnification of the different spectral components enables the regulation of the mid-infrared pulsed laser spectrum. Since the pump light and the signal light are always synchronized in time, the spectral control device for the mid-infrared pulse laser can be directly applied to the ultra-short pulse laser without flaw spread, and the mid-infrared ultrashort pulse on the femtosecond level The spectrum of the laser is regulated to increase its bandwidth and even shape it.

It is to be understood that those skilled in the art can make equivalent substitutions or changes to the inventions and the inventions of the present invention, and all such changes or substitutions fall within the scope of the appended claims.

Claims (6)

1.  A spectral control device for a mid-infrared pulsed laser, comprising:

   Near infrared pulsed laser ;

   Optical coupling mirror

   Non-periodic polarized crystal;

   a temperature control furnace for regulating the operating temperature of the non-periodically polarized crystal;

   Beam splitter

   The near-infrared pulse laser, the optical coupling mirror, the non-periodically polarized crystal, and the beam splitter are sequentially placed;

   a near-infrared pulsed laser emitted by a near-infrared pulsed laser passes through the optical coupling mirror, enters the non-periodically polarized crystal together with the mid-infrared pulsed laser, and uses a near-infrared pulsed laser as a pumping light through nonlinear frequency conversion. Differentiating the different spectral components of the mid-infrared pulsed laser; the mixed light of the non-periodically polarized crystal output A spectrally modulated mid-infrared pulsed laser is obtained after separation by the spectroscope.
2.  The spectral control device for a mid-infrared pulsed laser according to claim 1, wherein the non-periodically polarized crystal satisfies the matching of the class I level In the non-periodically polarized crystal, the polarization inversion period of the non-periodically polarized crystal changes non-periodically in the longitudinal direction.
3.  According to claim 1 The spectral control device for a mid-infrared pulsed laser is characterized in that the temperature at which the signal light is the same as the group velocity of the pump light in the non-periodically polarized crystal is the operating temperature.
4.  According to claim 1 The spectral control device for a mid-infrared pulsed laser is characterized in that the non-periodically polarized crystal is a non-periodically polarized lithium niobate crystal.
5.  The spectral control device for a mid-infrared pulsed laser according to claim 1, wherein the near-infrared pulse laser is 790 nm Ti:Sapphire femtosecond pulsed laser.
6. According to claim 1 The spectral control device for a mid-infrared pulsed laser is characterized in that the beam splitter is an optical element that can separate mixed light of different wavelengths from each other.