JP2003222752A - Polarized wave preserving photonic crystal fiber and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a polarized wave preserving photonic crystal fiber in which a mode of a Ti-diffused waveguide of an LN modulator can be matched to that of a quartz glass waveguide or the like of an AWG. <P>SOLUTION: The polarized wave preserving photonic crystal fiber 20 comprises a solid core 21a, and a clad 21b having a plurality of pores 21c arranged to form a predetermined lattice in a cross section of the fiber. The pore adjacent to the core 21a of the clad 21b has large pore size pores 21c' arranged as a pair via the core 21a, and small pore size pores 21c arranged as a pair via the core 21a so that a mode field of an optical propagation region perpendicularly cross with each other in the cross section of the fiber and has two polarized wave modes having different propagation constants. The large pore size pores 21c' are arranged to be deviated from a position for forming the predetermined lattice in a direction in which an aspect ratio of the pores 21c' is reduced. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a polarization maintaining photonic crystal fiber (hereinafter referred to as "polarization maintaining PFC").

[0002]

2. Description of the Related Art A photonic crystal fiber has a solid core forming the center of the fiber, and a photonic crystal structure formed in the radial direction of the fiber by forming a predetermined lattice on the cross section of the fiber so as to cover the core. It is an optical fiber provided with a clad having a plurality of pores arranged in such a manner as to be applied in various fields.

As one of them, as shown in FIG. 18A, a polarization-maintaining PC in which the propagation constant is made different in the major axis direction and the minor axis direction by making the core an elliptical shape.
There is F.

Also, Optic letters 2000.9 Vol.25 NO.1
As shown in FIG. 18 (b), a plurality of pores are provided in 8 so as to form a triangular lattice in the clad, and of the six pores adjacent to the core, they are opposed to each other with the core sandwiched therebetween. By making only the pores arranged on a straight line including a pair of small pores, the polarization with different propagation constants of the polarization mode in the direction in which the pores with small pores are lined up and the direction orthogonal to it A preserved PCF is disclosed. Such polarization-preserving PCF
In, it is possible to realize a mode birefringence of the order of 10 ⁻³ , which is a typical polarization maintaining fiber P
It is nearly an order of magnitude larger than ANDA fiber and has extremely excellent polarization conservation performance.

Furthermore, in OFC2001.TuM2 2001.3, FIG.
As shown in FIG. 8 (c), a plurality of pores are arranged in the clad so as to form a triangular lattice, and 6
By making one pair of the two pores that face each other across the core have a larger diameter than the other pores, the propagation constant of the polarization mode in the direction connecting the pores of both large diameters and the direction orthogonal to that is The mode birefringence is improved by arranging the large pores with different diameters and displacing them inward in the fiber radial direction by 80% of the pore pitch from the position where the triangular lattice is formed. An enhanced polarization preserving PCF is disclosed (shown in the core in the figure is the distribution of light intensity). In this polarization-maintaining PCF, the mode birefringence is 1.
It is calculated to be 5 × 10 ^−3, and the aspect ratio, which is the ratio of the mode field diameter in the direction orthogonal to the direction in which the large pores face each other, is approximately 2.0 or more from the figure. I can guess.

[0006]

In WDM communication today, a polarization maintaining fiber includes an LD light source (laser diode light source) and an LN modulator (lithium niobate modulator).
It is used as a pigtail for connecting the SC light source and the AWG (array waveguide) equipped with the SC light source (supercontinium light source) and the filter in the future. Furthermore, it is considered to be used as a pigtail that connects the AWG and the LN modulator.

By the way, the LN modulator uses a Ti diffusion waveguide having an aspect ratio of 1.5 as a waveguide, and the AWG has a quartz having an aspect ratio close to 1.0 as a waveguide. A glass waveguide is used.

Therefore, although the polarization-maintaining PCF disclosed in the latter document has a high mode birefringence,
Since the aspect ratio is high, there is a problem that it does not mode match with the Ti diffusion waveguide of the LN modulator or the silica glass waveguide of the AWG.

The present invention has been made in view of the above points, and an object of the present invention is to provide a polarization mode capable of mode matching with a Ti diffusion waveguide of an LN modulator or a silica glass waveguide of an AWG. It is to provide a wave-preserving PCF and a manufacturing method thereof.

[0010]

According to the present invention, pores are formed in a predetermined lattice so that the aspect ratio, which is the ratio of the mode field diameter of one of the two polarization modes to the mode field diameter of the other, is reduced. It is arranged by being offset from the position for forming the.

Specifically, a solid core forming the center of the fiber and a predetermined lattice formed on the core so as to cover the core to form a photonic crystal structure in the radial direction of the fiber are formed. A clad having a plurality of pores arranged therein, the pores adjacent to the core in the clad having a large pore diameter arranged in pairs with the core sandwiched therebetween; And a pair of small-diameter pores that are arranged in a pair with the polarization field sandwiched between the two polarization modes in which the mode fields, which are the light propagation regions, are orthogonal to each other in the cross section of the fiber and have different propagation constants. Given a polarization preserving PCF configured to have. At least one of the large-pore diameter and the small-pore diameter adjacent to the core has at least one of the two polarization mode directions in the mode field with respect to the other mode field diameter. It is characterized in that it is arranged so as to deviate from the position where the above-mentioned predetermined lattice is formed in the direction in which the aspect ratio, which is the ratio of the diameters, decreases.

According to the above construction, in addition to being able to obtain a high mode birefringence, at least one of the large pores and the small pores is displaced from the position where the predetermined lattice is formed. Since it is arranged so that the aspect ratio becomes small, that is, it approaches 1.0,
The aspect ratio becomes close to that of the Ti diffusion waveguide of the LN modulator or the silica glass waveguide of the AWG, and mode matching with them becomes possible.

Here, in the present application, the "aspect ratio" means one of the directions of the two polarization modes, whichever is smaller, except for the case where the mode field diameter of one is equal to the mode field diameter of the other. The mode field diameter, and the larger one is the other mode field diameter. Therefore, the aspect ratio is always 1.0 or more.

The size of the deviation of the pores is usually in the range of 0.1Λ to 0.9Λ when the lattice pitch is Λ.

In the case of a polarization-maintaining PCF, a mode birefringence of 10 ^-3 or more can be usually obtained, and therefore 1
The crosstalk at 00m is -30 dB or less, which is very small.

The aspect ratio of the present invention is preferably 1.0 or more and less than 2.0 in consideration of mode matching with a generally existing waveguide. Further, the aspect ratio is Considering a Ti diffusion waveguide having a ratio of 1.5 and a silica glass waveguide having an aspect ratio close to 1, the ratio is more preferably 1.0 or more and 1.7 or less.

The present invention may be arranged such that only large pores or small pores adjacent to the core are arranged so as to be displaced from the position where the predetermined lattice is formed. According to this structure, the photonic crystal structure of the clad is not greatly broken.

As a concrete constitution of the present invention, the large pores adjacent to the core are arranged so as to be displaced outward in the fiber radial direction from the position where the predetermined lattice is formed, or the core. There may be mentioned those in which the small pores adjacent to the above are arranged so as to be displaced inward in the fiber radial direction from the position where the above-mentioned predetermined lattice is formed.

According to the present invention, a pair of large pores having a large pore group including large pores arranged adjacent to each other in the fiber cross section and adjacent to the core are provided. And a pair of small pore size pore regions having a small pore size pore group including small pore size pores which are arranged so as to face each other across the core and are adjacent to the core. It is configured such that at least one of the respective pores of the large pore size pore region and each of the small pore size pore region is arranged displaced from the position forming the predetermined lattice. Good.

Specific configurations thereof include one in which each of the pores in the large pore area is displaced outward from the position forming the predetermined lattice in the radial direction of the fiber, and the small pore area. The pores may be arranged so as to be displaced inward in the radial direction of the fiber from the position where the predetermined lattice is formed.

In the polarization maintaining PCF as described above, a base material is formed by forming a plurality of holes in the rod material made of quartz and extending in the axial direction of the rod so as to correspond to the hole pattern of the fiber cross section. It can be manufactured through a step and a wire drawing step of reducing the diameter of the base material by wire drawing.

In this manufacturing method, wire drawing may be performed with the plurality of holes of the base material sealed.
By doing so, the force acting in the direction of crushing the hole of the base material by the drawing tension during the drawing process is balanced with the pressure inside the hole, and the drawing process can be performed without the hole being crushed. Here, the term "sealing" means all means for preventing the entry of outside air into the plurality of holes of the base material.

In that case, it is preferable to perform an impurity removal treatment for removing impurities on the inner walls of the plurality of holes before sealing the plurality of holes. In this way, the impurities in the holes of the base material can be removed, and thus the polarization-maintaining PC to be manufactured.
F has a low loss. Examples of the impurity removal treatment include etching treatment with hydrofluoric acid and chlorine gas treatment for removing hydroxyl groups by exposing to chlorine gas.

Further, the polarization-preserving PCF having a coating portion provided so as to coat the clad, the rod material made of quartz is provided so as to correspond to the hole pattern of the fiber cross section. A boring step of forming a plurality of holes extending in the axial direction, a base material main body forming step of forming a base material main body by reducing the diameter by heating and stretching the rod material in which the plurality of holes are formed in the rod axial direction, The base material is composed of the base material body and the quartz covering portion forming material that becomes the covering portion,
It can also be manufactured through a wire drawing process in which the diameter of the base material is reduced by wire drawing.

In this case, the base material main body is placed in a cylindrical covering portion forming material made of quartz to form a base material, and the base material is drawn to form the base material main body and the covering portion. Even if the diameter of the base material is reduced while being integrated with the base material, the base material main body is formed with a silica-based material by depositing and integrating the base material to form a cover portion forming material that serves as the cover portion, and the base material is formed by them. Alternatively, the diameter of the base material may be reduced by drawing.

In this manufacturing method, wire drawing may be performed in a state in which the plurality of holes of the base material body are sealed. With this configuration, the force that acts in the direction of crushing the hole of the base material body due to the drawing tension during the drawing process is balanced with the pressure inside the hole, and the drawing process can be performed without the hole being crushed. Here, the term "sealing" means all means for preventing outside air from entering the plurality of holes of the base material body.

In this case, it is preferable to perform an impurity removal treatment for removing impurities on the inner walls of the plurality of holes before sealing the plurality of holes. By doing so, impurities in the holes of the base material body can be removed, so that the polarization-maintaining PCF manufactured has low loss. Examples of the impurity removal treatment include etching treatment with hydrofluoric acid and chlorine gas treatment for removing hydroxyl groups by exposing to chlorine gas.

Further, in any of the manufacturing methods, it is preferable that the quartz rod material is made of anhydrous synthetic glass having a hydroxyl group content of 1 ppm or less. By doing so, the number of hydroxyl groups contained in the manufactured polarization-maintaining PCF is small and the loss is low.

[0029]

As described above, according to the present invention,
The aspect ratio becomes close to that of the Ti diffusion waveguide of the LN modulator or the silica glass waveguide of the AWG, and mode matching with them becomes possible.

[0030]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below in detail with reference to the drawings.

(Embodiment 1) <Structure of Polarization Preserving PCF> FIG. 1 shows Embodiment 1 of the present invention.
2 shows a polarization-maintaining PCF 20 according to the present invention. FIG. 2 shows the central part of the cross section.

This polarization-preserving PCF 20 is made of quartz (SiO 2).
₂ ), which is formed of a solid core 21a forming the center of the fiber and a clad 21b provided so as to cover the core 21a;
The coating portion 22 is provided so as to further cover the cladding 21b of the fiber body 21.

The cladding 21b is provided with a plurality of pores, which form a triangular lattice in the cross section of the fiber to form a photonic crystal structure in the radial direction of the fiber.

In the cross section of the fiber, of the six pores adjacent to the core 21a, the pair of pores 21c 'arranged so as to face each other with the core 21a interposed therebetween is the other pore 21c.
While the diameter of the core 2 is larger than that of the core 2, the other two pairs of pores 21c arranged so as to face each other with the core 21a interposed therebetween are
It has a small hole diameter that is the same as that of the pores 21c other than those adjacent to 1a. As a result, the polarization-maintaining PCF 20 has two polarization modes in which the mode fields, which are the light propagation regions, are orthogonal to each other in the cross section of the fiber and have different propagation constants.

The large pores 21c 'are arranged so as to be displaced outward in the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG. 2, that is, away from the core 21a. The direction of the displacement of this arrangement position is
Among the two polarization modes in the mode field, the aspect ratio, which is the ratio of the diameter of one mode field to the diameter of the other mode, decreases. Thus, only the large-diameter pores 21c 'are arranged so as to be displaced from the position where the triangular lattice is formed.

The polarization-preserving PCF 20 has an aspect ratio of 1.0 or more and less than 2.0 (preferably 1.
0 or more and 1.7 or less).

According to the polarization-maintaining PCF 20 having the above configuration, in addition to being able to obtain a high mode birefringence,
Since the large-diameter pores 21c 'are arranged so as to be displaced outward in the fiber radial direction from the position where the triangular lattice is formed, the aspect ratio is lowered thereby, so that the fiber L
It becomes close to the aspect ratio of the Ti diffusion waveguide of the N modulator and the silica glass waveguide of the AWG, etc., and mode matching with them becomes possible.

Further, since only the large pores 21c 'are arranged so as to be displaced from the position where the triangular lattice is formed, the photonic crystal structure of the clad 21b does not largely collapse.

<Method of Manufacturing Polarization-Maintaining PCF> Next, a method of manufacturing the polarization-maintaining PCF 20 according to the first embodiment of the present invention will be described step by step.

-Preparation Step-As shown in FIG. 3, a cylindrical rod material 1 made of quartz is prepared. As the rod material 1, one made of anhydrous synthetic glass having a hydroxyl group content of 1 ppm or less is used.

-Punching Step- As shown in FIG. 3, the prepared rod material 1 is left solid as the core forming portion 1a with the central axis portion as the core forming portion 1a, and is axially surrounded so as to surround the core forming portion 1a. The cladding forming portion 1b is formed by arranging a plurality of extending through holes 1c. These holes 1c are used for the polarization maintaining PCF 20.
The clad 21b is arranged so as to form a fine pore pattern. The holes are formed by, for example, drilling with a drill, rough finishing with a rod-shaped polishing tool, intermediate finishing, final finishing, and final polishing with a brush and a cerium oxide abrasive.

-Base material main body forming step-The rod material 1 on which the core forming portion 1a and the clad forming portion 1b are formed is set in an electric furnace drawing machine, and as shown in FIG.
A rod material 1 is heated by a rod drawing heater 2 and is drawn to form a base material main body 3 having a reduced diameter. At this time, in the base material body 3 in which the rod material 1 has a reduced diameter, a plurality of holes 3c having a smaller hole diameter and a smaller hole spacing than those of the rod material 1 are held, and accordingly, the core forming portion 3a and the clad formation are formed. The portion 3b is smaller than that of the rod material 1.

-Impurity removing treatment step-The base material main body 3 is immersed in hydrofluoric acid to etch the surface, and impurities such as metal adhered to the surface of the base material main body 3 are removed.

Then, as shown in FIG. 5, after the auxiliary pipes 4 are welded to both ends of the base material body 3, respectively,
Under a temperature atmosphere of 1200 ° C., chlorine gas was sent to one of the auxiliary pipes 4 and was made to flow through the holes 3c of the base material body 3,
By performing the chlorine gas treatment for discharging from the other auxiliary pipe 4, the hydroxyl group formed on the inner wall of the hole 3c is removed.

-Sealing Step-After chlorine gas treatment, as shown in FIG. 6, both ends of both auxiliary pipes 4 were immediately heated and closed to seal both ends of the hole 3c of the base material body 3. Put in a state. At this time, chlorine gas may be enclosed in the holes.

-Drawing Step-As shown in FIG. 7, the base material main body 3 is arranged in a quartz cylindrical covering portion forming material 12 to form a base material 13, and the base material 13 is drawn. The polarization preserving PCF 20 is manufactured by integrating the base material main body 3 and the covering portion forming material 12 into a thin diameter by a drawing process in which the base material main body 3 is heated while being stretched by the heater 11. At this time, the inside of the gap between the base material main body 3 and the covering portion forming material 12 is depressurized to a negative pressure.

When the base material main body is heat-integrated with the covering portion forming material to form the base material and then the wire drawing is performed, there is a possibility that the hole diameter may vary in the process of heat integration. According to the method for manufacturing the polarization-preserving PCF 20, since the base material main body 3 and the covering portion forming material 12 are integrated at the time of drawing, it is possible to prevent the variation of the hole diameter.

During the drawing process, the inside of the space between the base material main body 3 and the covering portion forming material 12 is depressurized to a negative pressure to prevent air from being trapped between the fiber main body 21 and the covering portion 22. Therefore, it is possible to prevent the transmission loss of the manufactured polarization-maintaining PCF 20 from increasing due to such air confinement.

According to the manufacturing method of the polarization-preserving PCF 20 as described above, the rod material 1 having the plurality of holes 1c formed therein is heated and drawn to form the base material main body 3. Further, the error of the hole spacing is reduced at the stage of the base material body 3, and the polarization maintaining PCF 20 with high dimensional accuracy can be manufactured.

Further, since the plurality of holes 3c of the base material main body 3 are drawn in a sealed state, the drawing tension during the drawing work acts in the direction of crushing the holes 3c of the base material main body 3. The force balances the pressure in the hole, and the wire drawing process can be performed without the hole 3c being crushed.

Furthermore, as the cylindrical rod material 1 made of quartz, one made of anhydrous synthetic glass having a hydroxyl group content of 1 ppm or less is used, and moreover, before sealing the plurality of holes 3c of the base material body 3. Since the etching treatment with hydrofluoric acid for removing the metal or the like on the surface of the base material body 3 and the chlorine gas treatment for removing the hydroxyl group on the inner wall of the hole 3c are performed,
The polarization-preserving PCF 20 with low loss can be manufactured.

<Experiment 1> Polarization-maintaining PCFs of Example 1 and Comparative Example 1 below were prepared and their aspect ratios were determined.

Example 1 After forming holes in the hole pattern shown in FIG. 8A in a rod material of anhydrous synthetic quartz having a diameter of 45 mm prepared by VAD, the rod material was stretched to have a diameter of 6 mm, and a mother was formed. The material body was formed. At this time, the pore diameter D ₁ of the small pores 21c is 1.4 mm, the pore diameter D ₂ of the large pores 21c 'is 3.9 mm, and the pores of the small pores 21c are between the pores. The pitch P ₁ was 3.9 mm, and the pitch P ₂ from the center of the rod to the pores 21 c ′ having large pores was 4.7 mm. After the inside of the hole of the base material body is treated with chlorine gas to seal both ends, the outside diameter is 25 mm and the inside diameter is 8 m.
Example 1 was a polarization-maintaining PCF 20 that was placed at the center of a quartz glass tube of m and was drawn by using this as a base material to draw a fiber having a diameter of 125 μm.

The manufactured polarization-maintaining PCF 20 of Example 1
In the configuration, the pore diameter d ₁ of the small pore 21c is 1.0 μm.
m, the pore diameter d _{2 of} the large pores 21c ′ is 2.7 μm, the pore pitch Λ ₁ between the small pores 21c is 2.7 μm, and the pitch Λ ₂ from the fiber center to the large pores 21c ′.
Is 3.2 .mu.m (that is, from the position where the large pores 21c 'form a triangular lattice to the outer side in the radial direction of the fiber of 0.
They are arranged so as to be offset by 19Λ ₁ . )Met. For this polarization-maintaining PCF 20, the light intensity distribution was measured at a wavelength of 1.55 μm to confirm single mode transmission, and the diameter at which the light intensity was 1 / e ² of the maximum value at the center was measured (the light intensity distribution is Gaussian. In the case of distribution, the diameter at which the light intensity is 1 / e ² of the maximum value of the center is the mode field diameter). As a result, the major axis is 4.4 μm and the minor axis is 3.5 μm,
Therefore, the aspect ratio was 1.26. Further, the mode birefringence was 1.6 × 10 ⁻³ , which showed high polarization conservation. The above characteristics are shown in Table 1.

[0055]

[Table 1]

-Comparative Example 1- Both the pitch P ₁ between the pores having the small pores 210c and the pitch P ₂ from the center of the rod to the pores having the large pores 210c 'are 3.9 mm. Then, a polarization-maintaining PCF 200 manufactured in the same manner as in Example 1 was used as Comparative Example 1.

The manufactured polarization-maintaining PCF 20 of Comparative Example 1
8 has a small hole diameter 210c as shown in FIG.
Pore pitch Λ between pores of₁And a large hole from the center of the fiber
Pitch Λ up to pore 210c '₂2.7μ for both
Same as Example 1 except m. wavelength
Measure the light intensity distribution at 1.55 μm and
Confirmed delivery. For this polarization-preserving PCF200,
Single mode by measuring the light intensity distribution at a length of 1.55 μm
Confirm the transmission, the light intensity is 1 / e of the maximum value of the center ²Becomes
The diameter was measured. As a result, the major axis is 4.4 μm and the minor axis is
2.9 μm, so with an aspect ratio of 1.52
there were. The mode birefringence is 1.7 × 10.^-3And
As a result, high polarization preserving property equivalent to that of Example 1 was exhibited. More than
The characteristics are shown in Table 2.

[0058]

[Table 2]

-Experimental Results- As described above, the aspect ratio is such that the large pores 21c 'have a large diameter.
The example 1 in which the holes are displaced from the position where the triangular lattice is formed is smaller than the comparative example 1 in which the large-diameter pores 210c ′ are arranged at the positions where the triangular lattice is formed.

(Second Embodiment) <Structure of Polarization Preserving PCF> FIG. 9 shows a second embodiment of the present invention.
2 shows a polarization-maintaining PCF 20 according to the present invention. The same parts as those in the first embodiment are designated by the same reference numerals.

In this polarization-maintaining PCF 20, of the six pores adjacent to the core 21a in the cross section of the fiber, the pair of pores 21c 'disposed so as to face each other with the core 21a sandwiched therebetween is the other thin pore. While the diameter of the pores is larger than that of the holes 21c, the other two pairs of pores 21c arranged to face each other with the core 21a interposed therebetween have the same diameter as the pores 21c other than those adjacent to the core 21a. It has a small hole diameter. As a result, the polarization-maintaining PCF 20 has two polarization modes in which the mode fields, which are the light propagation regions, are orthogonal to each other in the cross section of the fiber and have different propagation constants.

The large pores 21c 'adjacent to the core 21a are directed outward in the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG.
It is arranged so as to be away from a. The direction of the displacement of the arrangement position is such that the aspect ratio, which is the ratio of the mode field diameter of one of the two polarization modes in the mode field to the mode field diameter of the other, becomes smaller. Also, two large pores 2
The outer small pores 21c on the line connecting 1c 'are also outward in the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG. 9, that is, the direction away from the core 21a. It is arranged so as to be offset.

In the polarization-preserving PCF 20 having the above-described structure, when the large pores 21c 'have large pores and are arranged so as to be displaced from the position where the triangular lattice is formed, the large pores 21c' are arranged. ′ Is prevented from interfering with the small pores 21c on the outside.

Other configurations, operations and effects, and a manufacturing method are the same as those in the first embodiment.

<Experiment 2> Polarization-maintaining PCFs of Example 2 and Comparative Example 2 below were prepared and their aspect ratios were determined.

Example 2 After forming holes of the hole pattern shown in FIG. 10 (a) in a rod material of anhydrous synthetic quartz having a diameter of 45 mm prepared by VAD, it was stretched to a diameter of 6 mm and mother The material body was formed. At this time, the pore diameter D ₁ of the small pores 21c is 2.7 mm, the pore diameter D ₂ of the large pores 21c 'is 6.7 mm, and the pores of the small pores 21c are between the pores. The pitch P ₁ was 5.8 mm, and the pitch P ₂ from the center of the rod to the pores 21 c ′ having large pores was 7.0 mm. After the inside of the hole of the base material body is treated with chlorine gas to seal both ends, the outside diameter is 25 mm and the inside diameter is 8 m.
Example 2 was a polarization-maintaining PCF 20 that was placed at the center of a quartz glass tube of m and was drawn by using this as a base material to draw a fiber having a diameter of 125 μm.

The manufactured polarization-maintaining PCF 20 of Example 2
In the configuration, the pore diameter d ₁ of the small pore 21c is 1.9 μm.
m, the pore diameter d _{2 of} the large pores 21c ′ is 4.7 μm, the pore pitch Λ ₁ between the small pores 21c is 4.0 μm, and the pitch Λ ₂ from the center of the fiber to the large pores 21c ′.
Is 4.8 μm (that is, the large pores 21c ′ and the outer small pores 21c each have a diameter 0.20Λ ₁ outward from the position where the triangular lattice is formed, respectively.
They are arranged in a staggered manner. )Met. This polarization conservation P
For CF20, the light intensity distribution was measured at a wavelength of 1.55 μm to confirm single mode transmission, and the diameter at which the light intensity was 1 / e ² of the maximum value at the center was measured. As a result, the major axis was 6.1 μm and the minor axis was 4.4 μm, and thus the aspect ratio was 1.39. Further, the mode birefringence is 1.4 × 10 ^−3, which is slightly lower than that in Example 1, but the mode field diameter is large, so it can be said that the connectivity with other optical fibers is excellent. The above characteristics are shown in Table 3.

[0068]

[Table 3]

[0069] - 5.8 mm to any of the pitch P ₁ of the pitch P ₁ and the rod center between hole of what the Comparative Example 2 small pore diameter of the pores 210c to which the pores 210c 'of the large pore Then, a polarization-maintaining PCF200 manufactured in the same manner as in Example 1 was used as Comparative Example 2.

The polarization-maintaining PCF 20 of Comparative Example 2 produced
In the configuration of _No. 0, as shown in FIG. 10B, both the hole pitch Λ ₁ between the small pores 210c and the pitch Λ ₂ from the fiber center to the large pore 210c 'are 4.0.
The same as Example 1 except that the thickness was μm. For this polarization-maintaining PCF200, the light intensity distribution was measured at a wavelength of 1.55 μm to confirm single mode transmission, and the diameter at which the light intensity was 1 / e ² of the maximum value at the center was measured. As a result, the major axis was 6.1 μm and the minor axis was 3.5 μm,
Therefore, the aspect ratio was 1.71. Moreover, the mode birefringence was 1.5 × 10 ⁻³ , which was equivalent to that of Example 2. The above characteristics are shown in Table 4.

[0071]

[Table 4]

-Experimental Results- As described above, the aspect ratio is that of the large pores 21c '.
Example 2 in which the small pores 21c on the outside and the small pores 21c are arranged offset from the position where the triangular lattice is formed is comparative example in which the large pores 210c 'are arranged at the position where the triangular lattice is formed. Less than 2.

(Third Embodiment) <Structure of Polarization Preserving PCF> FIG. 11 shows a polarization preserving PCF 20 according to a third embodiment of the present invention. The first embodiment
The same parts as are indicated by the same reference numerals.

In this polarization-maintaining PCF 20, in the cross section of the fiber, among the six pores adjacent to the core 21a, on a straight line connecting a pair of pores 21c arranged so as to face each other with the core 21a interposed therebetween. Some pores have a smaller pore diameter than other pores, while other pores including two pairs of other pores 21c ′ arranged so as to face each other with the core 21a interposed therebetween have a larger pore diameter. It is a thing. Further, in the cross section of the fiber, a pair of regions having a large pore group including large pores 21c ′ adjacent to the core 21a arranged so as to face each other across the core 21a is a large pore region. On the other hand, a pair of regions having a small pore size pore group including small pore size small pores 21c that are arranged to face each other with the core 21a sandwiched therebetween and that are adjacent to the core 21a Three
Make up 2. With the above configuration, polarization preserving PC
The mode field in which F20 is a light propagation region has two polarization modes that are orthogonal to each other in the cross section of the fiber and have different propagation constants.

The small pores 21c adjacent to the core 21a are directed inward in the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG.
They are arranged so as to be closer to a. The direction of the displacement of the arrangement position is such that the aspect ratio, which is the ratio of the mode field diameter of one of the two polarization modes in the mode field to the mode field diameter of the other, becomes smaller. Further, the small pores 21c outside the small pores 21c on the line connecting the small pores 21c adjacent to the core 21a are also located inside the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG. Orientation, that is,
The cores 21a are arranged so as to shift toward the core 21a. That is, each of the small pores 21c ′ of the large pore diameter pore area 31 is arranged at a position forming a triangular lattice, while the small pore diameter pore area 3 is formed.
Each of the two small holes 21c is arranged so as to be displaced outward in the fiber radial direction from the position where the triangular lattice is formed.

In the polarization-maintaining PCF 20 having the above structure, the zero dispersion wavelength is shifted to the short wavelength side because the ratio of the hole diameter of the holes to the hole interval of the photonic crystal structure formed in the cladding 21b is large overall. It is a thing.

Other configurations, operations and effects, and manufacturing method are the same as those in the first embodiment.

<Experiment 3> Polarization-maintaining PCFs of Example 3 and Comparative Example 3 below were prepared and their aspect ratios were determined.

Example 3 After forming holes of the hole pattern shown in FIG. 12 (a) in a rod material of anhydrous synthetic quartz having a diameter of 45 mm prepared by VAD, it was stretched to a diameter of 6 mm and mother The material body was formed. At this time, the pore diameter D ₁ of the small pores 21c is 1.0 mm, the pore diameter D ₂ of the large pores 21c 'is 2.3 mm, and the pores of the small pores 21c are between the pores. The pitch P ₁ was 3.3 mm, and the pitch P ₂ from the center of the rod to the pores 21 c ′ having a large hole diameter was 2.8 mm. After the inside of the hole of the base material body is treated with chlorine gas to seal both ends, the outside diameter is 25 mm and the inside diameter is 8 m.
Example 3 was a polarization-maintaining PCF 20 which was placed at the center of a quartz glass tube of m and was drawn by using this as a base material to draw a fiber having a diameter of 125 μm.

The manufactured polarization-maintaining PCF 20 of Example 3
Is configured such that the pore diameter d ₁ of the small pore 21c is 0.7 μm.
m, the pore diameter d _{2 of} the large pore 21c ′ is 1.6 μm, the pore pitch Λ ₁ between the small pores 21c is 2.3 μm, and the pitch Λ ₂ from the center of the fiber to the large pore 21c ′.
Is 2.0 μm (that is, 0.1 inward from the position where the small pores 21c form a triangular lattice in the radial direction of the fiber).
It is arranged with a deviation of 3Λ ₁ . )Met. The aspect ratio was 1.10. Further, the mode birefringence was 1.6 × 10 ⁻³ , which showed high polarization conservation. The above characteristics are shown in Table 5.

[0081]

[Table 5]

[0082] - 3.3 mm and even one from the pitch P ₁ and the rod center between hole of what the Comparative Example 3 small pore diameter of the pores 210c of the pitch P ₂ to which the pores 210c 'of the large pore Then, the polarization-maintaining PCF200 manufactured in the same manner as in Example 1 was used as Comparative Example 3.

The manufactured polarization-maintaining PCF 20 of Comparative Example 3
In the configuration of 0, as shown in FIG. 12B, both the hole pitch Λ ₁ between the small holes 210c and the pitch Λ ₂ from the center of the fiber to the large hole 210c 'are 2.3.
The same as Example 1 except that the thickness was μm. The aspect ratio was 1.30. Moreover, the mode birefringence was 1.6 × 10 ⁻³ , which was equivalent to that of Example 3. The above characteristics are shown in Table 6.

[0084]

[Table 6]

-Experimental Results- As described above, the aspect ratio of Example 3 was such that the small pores 21c were displaced from the positions forming the triangular lattice.
Is smaller than Comparative Example 3 in which the small pores 210c are arranged at the positions forming the triangular lattice.

(Fourth Embodiment) <Configuration of Polarization Preserving PCF> FIG. 13 shows a polarization preserving PCF 20 according to a fourth embodiment of the present invention. The first embodiment
The same parts as are indicated by the same reference numerals.

In this polarization-maintaining PCF 20, in the cross section of the fiber, among the six pores adjacent to the core 21a, on a straight line connecting a pair of pores 21c 'arranged so as to face each other with the core 21a sandwiched therebetween. While the pores in FIG. 3 have a larger diameter than the other pores, the other pores including the other two pairs of pores 21c arranged so as to face each other with the core 21a interposed therebetween have a smaller pore diameter. It is a thing. Further, in the cross section of the fiber, a pair of regions having a large pore group including large pores 21c ′ adjacent to the core 21a arranged so as to face each other across the core 21a is a large pore region. On the other hand, a pair of regions having a small pore size pore group including small pore size small pores 21c that are arranged to face each other with the core 21a sandwiched therebetween and that are adjacent to the core 21a Three
Make up 2. With the above configuration, polarization preserving PC
The mode field in which F20 is a light propagation region has two polarization modes that are orthogonal to each other in the cross section of the fiber and have different propagation constants.

The large pores 21c 'adjacent to the core 21a are directed inward in the fiber radial direction from the position forming the triangular lattice shown by the phantom line in FIG.
It is arranged so as to be away from 1a. The direction of the displacement of the arrangement position is such that the aspect ratio, which is the ratio of the mode field diameter of one of the two polarization modes in the mode field to the mode field diameter of the other, becomes smaller. Also, the large pores 21c ′ on the outside of the large pores 21c ′ adjacent to the core 21a, which are on the line connecting the large pores 21c ′, are also separated from the positions forming the triangular lattice as shown by the phantom lines in FIG. The fibers are arranged outward in the radial direction of the fiber, that is, in a direction away from the core 21a. In other words, the pores 21c of the small pore area 32 are arranged at the positions forming the triangular lattice, while the pores 21c 'of the large pore area 31 form the triangular lattice at the fiber radius. It is arranged so as to be shifted outward in the direction.

In the first and second embodiments, the core 21a is used.
Since there is a small-pore 21c 'outside the large-pore 21c' adjacent to, there is a possibility that long-wavelength light may be emitted in that direction and long-wavelength transmission may be interrupted. In the polarization-preserving PCF 20 having the configuration, the larger pore 21c ′ is provided outside the large pore 21c ′ adjacent to the core 21a.
Therefore, such inconvenience is eliminated.

Other configurations, operations and effects, and the manufacturing method are the same as those in the first embodiment.

(Other Embodiments) First to Fourth Embodiments
Then, the base material main body 3 is arranged in the cylindrical covering portion forming material 12 made of quartz, and the base material 13 is constituted by them, and the base material 13 is heated by the drawing heater 11 and is drawn by a drawing process. The polarization-maintaining PCF 20 was manufactured by integrating the base material main body 3 and the covering portion forming material 12 and reducing the diameter, but the invention is not particularly limited to this, and as shown in FIG.
Quartz particles produced by supplying SiCl ₄ to the flame of the oxyhydrogen burner 5 are deposited and integrated on the outer periphery of the base material body 3 in which the holes 3c are sealed to form a quartz porous layer 6, and then, as shown in FIG.
As shown in FIG. 5, by disposing the base material body 3 in which the quartz porous layer 6 is integrally deposited on the outer periphery in the heating container 7 in which helium and chlorine gas are circulated, and heating by the firing heater 8 from the outside. After the quartz porous layer 6 is fired to be changed into the transparent covering portion forming material 9 to form a base material 10, the base material 10 is set in a wire drawing device, and as shown in FIG. The diameter may be reduced by drawing.

Also, a base material forming step of forming a base material by forming a plurality of holes extending in the rod axial direction so as to correspond to a hole pattern of a fiber cross section in a quartz rod material, and drawing the base material. The polarization-maintaining PCF may be manufactured through a wire drawing process for reducing the diameter. in this case,
If drawing work is performed with multiple holes in the base material sealed, the force that acts in the direction to crush the holes in the base material due to the drawing tension during drawing work balances the pressure inside the holes, and Wire drawing can be performed without being crushed.
Further, if the impurity removal treatment for removing the impurities on the inner walls of the plurality of holes is performed before the plurality of holes are sealed, the impurities in the holes of the base material can be removed, so that the manufacturing process is performed. The polarization-maintaining PCF has low loss. Furthermore, if the rod material made of quartz is made of anhydrous synthetic glass having a hydroxyl group content of 1 ppm or less, the number of hydroxyl groups contained in the polarization-maintaining PCF produced is small and the loss is low.

Further, in the third embodiment, the small pore diameter pore region 32 is constituted by a pair of strip-shaped regions sandwiching the core 21a in the cross section of the fiber, while the large pore diameter pore region 31 is constituted in the other regions. In the fourth embodiment, the large pore diameter pore region 31 is constituted by a pair of strip-shaped regions sandwiching the core 21a in the fiber cross section, while the small pore diameter pore region 32 is constituted in other regions. However, as shown in FIG. 17, the large-pore-diameter pore area 31 and the small-pore-diameter pore area 32 are respectively constituted by fan-shaped areas having a center angle of 60 ° or 120 ° around the core 21a. You may do it.

Further, in the above-mentioned Embodiments 1 to 3, the polarization-maintaining PCF 20 made of pure quartz is used, but the invention is not particularly limited to this, and if the main component is quartz, other elements may be used. It may be doped.

Further, in the above-described first to third embodiments, the pores are arranged in the clad 21b so as to form a triangular lattice.
The material is not particularly limited to this, and any material such as a square lattice or a honeycomb lattice may be used as long as it has a photonic crystal structure in the clad.

[Brief description of drawings]

FIG. 1 is a perspective view of a polarization maintaining PCF according to a first embodiment.

FIG. 2 is a front view of a central portion of a cross section of the polarization-maintaining PCF according to the first embodiment.

FIG. 3 is an explanatory diagram of a preparation process and a punching process according to the first embodiment.

FIG. 4 is an explanatory diagram of a base material main body forming step according to the first embodiment.

FIG. 5 is an explanatory diagram of chlorine gas treatment in the impurity removal treatment step according to the first embodiment.

FIG. 6 is an explanatory diagram of a sealing process according to the first embodiment.

FIG. 7 is an explanatory diagram of a wire drawing process according to the first embodiment.

8 is a front view of the central portion of the cross section of the polarization-maintaining PCFs of Example 1 and Comparative Example 1 of Experiment 1. FIG.

FIG. 9 is a front view of a central portion of a cross section of a polarization-maintaining PCF according to a second embodiment.

10 is a front view of a central portion of a cross section of a polarization-maintaining PCF of each of Example 2 and Comparative Example 2 of Experiment 2. FIG.

FIG. 11 is a front view of a central portion of a cross section of a polarization-maintaining PCF according to a third embodiment.

12 is a front view of a central portion of a cross section of a polarization-maintaining PCF of each of Example 3 and Comparative Example 3 of Experiment 3. FIG.

FIG. 13 is a front view of a central portion of a cross section of a polarization-maintaining PCF according to a fourth embodiment.

FIG. 14 is an explanatory diagram showing a process of forming a quartz porous layer in a coating portion forming material forming step according to a method for manufacturing a polarization-maintaining PCF of another embodiment.

FIG. 15 is an explanatory diagram showing a process of forming a coating portion forming material by firing a quartz porous layer in a coating portion forming material forming step according to a method of manufacturing a polarization-maintaining PCF of another embodiment.

FIG. 16 is an explanatory diagram showing a drawing process according to a method of manufacturing a polarization-maintaining PCF of another embodiment.

FIG. 17 is a schematic front view of a central portion of a cross section of a polarization maintaining PCF according to another embodiment.

FIG. 18 is a front view of a central portion of a cross section of a polarization-maintaining PCF according to a conventional technique.

[Explanation of symbols]

1 Rod material 1a, 3a core forming part 1b, 3b clad forming part 1c, 3c holes 2 Rod stretching heater 3 Base material body 4 Auxiliary pipe 5 oxyhydrogen burner 6 Quartz porous layer 7 heating container 8 Firing heater 9,12 coating material 10,13 Base material 11 Wire drawing heater 20,200 Polarization-preserving PCF 21 Fiber body 21a, 210a core 21b, 210b clad 21c, 210c Small pore size 21c ', 210c' Large pores 22 Cover 31 Large pore area 32 small pore area

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masatoshi Tanaka             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Moriyuki Fujita             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Satoru Kawanishi             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Kazunori Suzuki             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Hirokazu Kubota             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F-term (reference) 2H050 AA09 AB03Z AC45 AC62                 4G021 BA00

Claims (16)

[Claims] 1. A solid core that forms the center of a fiber, and a core is provided so as to cover the core and a predetermined lattice is formed in the cross section of the fiber so as to form a photonic crystal structure in the radial direction of the fiber. And a clad having a plurality of pores, the pores adjacent to the core in the clad having large pores arranged in pairs with the core sandwiched therebetween and the core sandwiched with the large pore diameter. And a pair of small pores arranged in pairs so that the mode fields, which are light propagation regions, have two polarization modes that are orthogonal to each other in the cross section of the fiber and have different propagation constants. In the polarization-maintaining photonic crystal fiber configured, at least one of a large-pore diameter and a small-pore diameter adjacent to the core is the above-mentioned in the mode field. One of the two polarization mode directions is displaced from the position where the above-mentioned predetermined grating is formed in a direction in which the aspect ratio, which is the ratio of the other mode field diameter to the other mode field diameter, becomes smaller. A polarization-preserving photonic crystal fiber. 2. The polarization maintaining photonic crystal fiber according to claim 1, wherein the aspect ratio is 1.0 or more and less than 2.0. 3. A polarization maintaining photonic crystal fiber according to claim 2, wherein the aspect ratio is 1.0 or more and 1.7 or less. 4. The polarization-maintaining photonic crystal fiber according to claim 1, wherein only the large pores or small pores adjacent to the core are displaced from the position where the predetermined lattice is formed. A polarization-maintaining photonic crystal fiber characterized by being installed. 5. The polarization-maintaining photonic crystal fiber according to claim 1, wherein the large-diameter pores adjacent to the core are displaced outward from the position forming the predetermined lattice in the fiber radial direction. A polarization-maintaining photonic crystal fiber characterized by being used. 6. The polarization-maintaining photonic crystal fiber according to claim 1, wherein the small pores adjacent to the core are displaced inward in the fiber radial direction from the position where the predetermined lattice is formed. A polarization-maintaining photonic crystal fiber characterized by being used. 7. The polarization-maintaining photonic crystal fiber according to claim 1, wherein the cross section of the fiber includes pores of a large pore size which are arranged so as to face each other with the core interposed therebetween and which are adjacent to the core. A pair of large pore size pore regions having a large pore size pore group, and a small pore size pore group including small pore size pores arranged so as to face each other across the core and adjacent to the core And a small pore size pore region of, and at least one of each pore of the large pore size pore region and each of the small pore size pore region forms the predetermined lattice. A polarization-maintaining photonic crystal fiber, which is arranged so as to be displaced from the position where 8. The polarization-maintaining photonic crystal fiber according to claim 7, wherein each of the pores in the large pore diameter pore region is displaced outward from the position where the predetermined lattice is formed in the fiber radial direction. A polarization-maintaining photonic crystal fiber characterized by being used. 9. The polarization-maintaining photonic crystal fiber according to claim 7, wherein each of the pores in the small-pore diameter pore region is displaced inward in the fiber radial direction from the position where the predetermined lattice is formed. A polarization-maintaining photonic crystal fiber characterized by being used. 10. A solid core which forms the center of the fiber, and a core which is provided so as to cover the core and which is arranged to form a photonic crystal structure in the radial direction of the fiber by forming a predetermined lattice in the cross section of the fiber. And a clad having a plurality of pores, the pores adjacent to the core in the clad having large pores arranged in pairs with the core sandwiched therebetween and the core sandwiched with the large pore diameter. And a pair of small pores arranged in pairs so that the mode fields, which are light propagation regions, have two polarization modes that are orthogonal to each other in the cross section of the fiber and have different propagation constants. In the direction of the two polarization modes in the mode field, one of the two polarization mode directions has a smaller aspect ratio, which is the ratio of the other mode field diameter to the other mode field diameter. A method of manufacturing a polarization-maintaining photonic crystal fiber, wherein at least one of a large-pore diameter and a small-pore diameter adjacent to a is arranged displaced from a position forming the predetermined lattice, A base material forming step of forming a base material by forming a plurality of holes extending in the rod axial direction in a rod material made of quartz so as to correspond to the hole pattern of the cross section of the fiber; And the wire drawing process,
A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising: 11. The polarization-maintaining photonic crystal fiber according to claim 10, wherein the drawing is performed in a state where a plurality of holes of the base material are sealed, and the polarization-maintaining photonic crystal fiber is drawn. Crystal fiber manufacturing method. 12. The method for manufacturing a polarization-maintaining photonic crystal fiber according to claim 11, wherein an impurity removal treatment for removing impurities on inner walls of the plurality of holes is performed before sealing the plurality of holes. A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising: 13. A solid core forming the center of the fiber and a core provided to cover the core and forming a photonic crystal structure in the radial direction of the fiber by forming a predetermined lattice in the cross section of the fiber. A clad having a plurality of pores and a covering portion provided so as to further cover the clad, and pores adjacent to the core in the clad are arranged in pairs with the core interposed therebetween. The mode fields, which are the light propagation regions, are orthogonal to each other in the cross section of the fiber due to the large pores provided and the small pores arranged in pairs with the core sandwiched therebetween. Of the two polarization modes having different propagation constants, and one of the directions of the two polarization modes in the mode field corresponds to the other mode field diameter. At least one of the large pores and the small pores adjacent to the core is arranged to be displaced from the position where the predetermined lattice is formed in the direction in which the aspect ratio, which is the ratio of the diameter of the holes, decreases. A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising a step of forming a plurality of holes extending in a rod axial direction in a rod material made of quartz so as to correspond to the hole pattern of the fiber cross section, Forming a base material main body by thinning the rod material having the holes formed therein by heating and stretching in the axial direction of the rod to form a base material main body; And a drawing step of reducing the diameter of the base material by a drawing process. A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising: 14. The method of manufacturing a polarization-preserving photonic crystal fiber according to claim 13, wherein the drawing is performed in a state where a plurality of holes of the base material body are sealed, and a polarization-preserving photo. Nick crystal fiber manufacturing method. 15. The method for manufacturing a polarization-maintaining photonic crystal fiber according to claim 14, wherein before the sealing of the plurality of holes, an impurity removing process for removing impurities on the inner walls of the plurality of holes is performed. A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising: 16. The method for producing a polarization maintaining photonic crystal fiber according to claim 10 or 13, wherein the quartz rod material is formed of anhydrous synthetic glass having a hydroxyl group content of 1 ppm or less. A method of manufacturing a polarization-maintaining photonic crystal fiber, comprising: