JP2019021922A - Rare earth element doped optical fiber, and method for improving radiation resistance of rare earth element doped optical fiber - Google Patents

Abstract

To provide a novel rare earth element doped optical fiber which includes a rare earth element and phosphorous in a core part, nonetheless has high radiation resistance and is hard to be reduced in gain even when used in an environment where radiation is present.SOLUTION: The rare earth element doped optical fiber includes: a core portion; and a clad portion covering the periphery of the core portion. The core portion includes erbium, ytterbium, phosphorus, and germanium.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a rare earth element-doped optical fiber and a method for improving the radiation resistance of a rare earth element doped optical fiber.

  An optical fiber generally has a core part and a clad part that covers the core part. In this type of optical fiber, the refractive index of the core part is made larger than the refractive index of the cladding part, and the light is totally reflected at the boundary between the core part and the cladding part. Propagate far away as a signal.

The optical fiber is also used as an amplifier. As an optical fiber for an amplifier, a rare earth element-doped optical fiber in which a rare earth element is added to a core portion is known. An Er-doped optical fiber doped with erbium (Er) as a rare earth element is used as an amplifier in the 1.55 μm band.
In a rare earth element-doped optical fiber used as an amplifier, it is effective to increase the content of the rare earth element in the core portion in order to improve the gain. However, if the content of rare earth elements (especially Er) is excessively increased, clustering (raising) of rare earth elements may occur, concentration quenching may occur, and the gain may decrease. In order to prevent the generation of clustering between the rare earth elements, in the rare earth element-doped optical fiber, the rare earth elements are dispersed by co-adding phosphorus (P) or aluminum (Al) to the core portion. .

  With the progress of optical communication technology in recent years, optical fibers have been used in various environments. For example, optical fibers are also used in environments where radiation is present, such as outer space and nuclear power plants. However, an optical fiber in which a metal element is added to the core portion has a problem that it is easily deteriorated by radiation (particularly, electromagnetic radiation such as X-rays and γ rays).

  For example, it is known that an optical fiber to which Ge is added in order to improve the refractive index of the core portion of the optical fiber is inferior in radiation resistance as compared with a pure silica core optical fiber. For this reason, it has been studied to increase the refractive index of the core without using Ge. In Patent Document 1, as a method for increasing the refractive index of the core without using Ge, a quartz vitreous cladding containing high-concentration fluorine is used as the cladding, and the cladding is lower in refractive index than the core. Thus, a method for relatively increasing the refractive index of the core portion is disclosed.

  In addition, rare earth element-doped optical fibers in which P or Al is added to the core portion to prevent the occurrence of clustering of rare earth elements, when irradiated with radiation, light defect absorption is generated and the gain decreases. It has been known. This defect absorption of light is attributed to P and Al added to the core.

  In Patent Document 2, as a rare earth element-doped optical fiber that does not require the addition of any other radiation-sensitive dopant, the rare earth element includes a core matrix and a rare earth-doped silica-based nanoparticle. An element doped optical fiber is disclosed. In the rare earth element-doped optical fiber disclosed in Patent Document 2, a silica-based matrix containing no phosphorus or aluminum is used as the core matrix.

  Patent Document 3 discloses co-doping cerium (Ce) in the core portion in order to suppress a decrease in gain due to radiation caused by phosphorus. In Patent Document 3, a rare earth element is added in which the core has an erbium concentration of 100 to 1000 ppm, an ytterbium concentration of 500 to 10,000 ppm, a phosphorus concentration of 2 to 10 atomic%, and a cerium concentration of 500 to 10,000 ppm. An optical fiber is described.

JP 60-257408 A JP 2010-135801 A US Patent Application Publication No. 2013/0101261

  An object of the present invention is to provide a novel rare earth element-doped optical fiber having excellent radiation resistance. That is, the present invention provides a novel rare earth element-doped optical fiber that has a high radiation resistance while containing a rare earth element and phosphorus in the core, and is less likely to reduce gain even when used in an environment where radiation exists. With the goal. Another object of the present invention is to provide a novel method for improving the radiation resistance of a rare earth element-doped optical fiber containing a rare earth element and phosphorus in the core.

  In order to solve the above problems, a rare earth element-doped optical fiber of the present invention has a core portion and a cladding portion that covers the periphery of the core portion, and the core portion contains erbium, ytterbium, phosphorus, and germanium. It is characterized by including.

  In the rare earth element-doped optical fiber of the present invention, the erbium content is 0.05% by mass or more, and the phosphorus content is 18 to 360 in terms of a mass ratio P / Er of the phosphorus to the erbium. And the germanium content may be 0.5 mass% or more and 12.0 mass% or less.

  In the rare earth element-doped optical fiber of the present invention, the ytterbium content may be 4 to 50 in terms of the mass ratio Yb / Er of the ytterbium and the erbium.

  In the rare earth element-doped optical fiber of the present invention, the core portion may contain cerium, and the cerium content may be 0.12% by mass or less.

  In the rare earth element-doped optical fiber of the present invention, the core portion may include aluminum, and the content of the aluminum may be less than 1.0 in terms of a mass ratio Al / P between the aluminum and the phosphorus. .

  In the rare earth element-doped optical fiber of the present invention, the core portion may contain boron, and the boron content may be 0.6% by mass or less.

  A method for improving the radiation resistance of a rare earth element-doped optical fiber according to the present invention includes a core portion and a cladding portion covering the periphery of the core portion, and the core portion includes a rare earth element containing erbium, ytterbium, and phosphorus. A method for improving the radiation resistance of an doped optical fiber, characterized in that germanium is added to the core portion.

  According to the present invention, there is provided a novel rare earth element-doped optical fiber that has a high radiation resistance while containing a rare earth element and phosphorus in the core portion, and is difficult to reduce gain even when used in an environment where radiation exists. Is possible. In addition, according to the present invention, it is possible to provide a novel method for improving the radiation resistance of a rare earth element-doped optical fiber containing a rare earth element and phosphorus in the core portion.

6 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 1. FIG. 6 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform produced in Example 2. 6 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 3. 6 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 4. 6 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 5. 10 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 6. 10 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform produced in Example 7. 10 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 8. 10 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 9. 10 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 10. 14 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 11. 14 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform produced in Example 12. 14 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 13. 16 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 14. 16 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform produced in Example 15. 14 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 16. 18 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 17. 20 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 18. 20 is a graph showing a concentration distribution of an additive element in a rare earth element-doped optical fiber preform manufactured in Example 19. It is a graph which shows the concentration distribution of the addition element of the rare earth element addition optical fiber preform produced in Example 20. It is a graph which shows the absorption coefficient increase amount of the light after X-ray irradiation of the rare earth element addition optical fiber preform produced in Examples 1-10. It is a graph which shows the absorption coefficient increase amount of the light after X-ray irradiation of the rare earth element addition optical fiber preform produced in Examples 11-20. 4 is a graph showing an increase in absorption loss of light after γ-ray irradiation of rare earth element-doped optical fibers produced in Examples 1, 6, 8, 10 and Comparative Example 1. It is a graph which shows the increase amount of the light absorption loss after the gamma ray irradiation of the rare earth element addition optical fiber produced in Example 11, 12, 13, 18, 19, 21, 22, 23 and the comparative example 1. It is a graph which shows the relationship between Ge addition density | concentration of the core part of the rare earth element addition optical fiber produced in Examples 1-23 and Comparative Example 1, an X-ray-proof characteristic, and a gamma-ray resistant characteristic.

  Hereinafter, embodiments of a rare earth element-doped optical fiber and a method for improving the radiation resistance of the rare earth element doped optical fiber according to the present invention will be described.

  The rare earth element-doped optical fiber of the present embodiment has a core part and a clad part covering the periphery of the core part. The core part is formed of a silica composition containing erbium (Er), ytterbium (Yb), phosphorus (P), and germanium (Ge). The core part may further contain cerium (Ce), aluminum (Al), and boron (B) as necessary.

  The rare earth element-doped optical fiber of the present embodiment is an Er-doped optical fiber whose core part includes Er. The rare earth-doped optical fiber of this embodiment is used as an optical fiber such as a multimode optical fiber (MMF), a single mode optical fiber (SMF), a double clad optical fiber (DCF), or a polarization maintaining optical fiber. It can be made various forms. The rare earth element-doped optical fiber of this embodiment can be used, for example, as a 1.55 μm band light amplifier. The rare earth element-doped optical fiber of this embodiment is an optical communication device or optical fiber gyro mounted on a spacecraft (for example, a rocket, an artificial satellite or a spacecraft), an optical fiber amplifier in a nuclear reactor, or an optical communication device mounted on an aircraft. It can be suitably used in applications where radiation resistance is required.

Er contained in the core portion has an action of being excited by light (excitation light) having a wavelength of 0.98 μm or 1.48 μm to generate light (signal light) having a wavelength of 1.55 μm.
The Er content in the core part is preferably 0.05% by mass or more, particularly preferably 0.09% by mass or more. On the other hand, if the Er content is too large, concentration quenching may occur due to the occurrence of clustering. Therefore, it is necessary to co-add Yb and P within the ranges shown in the following paragraphs.

  Yb is excited by light in a wide wavelength range with a wavelength of 0.8 to 1.1 μm, and has an action of exciting Er by energy transition from the excited Yb to Er. With this action, the amount of light having a wavelength of 1.55 μm can be increased. Yb also has an action of suppressing the occurrence of Er clustering by coordinating around Er and increasing the distance between Er. With this action, Er concentration quenching can be suppressed even when the Er content is large, and this can also increase the amount of light generated at a wavelength of 1.55 μm. The Yb content of the core part is a mass ratio Yb / Er of Yb and Er, preferably in the range of 4 to 50, more preferably in the range of 4 to 40, and particularly preferably in the range of 4 to 20. . By setting the Yb content in the above range, the generation of light having a wavelength of 1.55 μm can be reliably increased.

P has the effect of suppressing the occurrence of Er clustering by coordinating around Er and increasing the distance between Er. With this action, Er concentration quenching can be suppressed even when the Er content is large, and thus the amount of light generated at a wavelength of 1.55 μm can be increased. P also has an effect of suppressing the excited state absorption (ESA) of Er and the reverse transfer of energy from excited Er to Yb.
The P content of the core part is a mass ratio P / Er of P and Er, and is preferably in the range of 18 or more and 360 or less. When the P content is in the above range, the occurrence of Er clustering can be reliably suppressed.

As shown in Examples described later, Ge has an action of suppressing radiation generation due to radiation caused by P and improving radiation resistance.
The inventor of the present invention added various elements to the core portion in order to improve the radiation resistance of the rare earth element-doped optical fiber containing P. As a result, unexpectedly, the addition of Ge, which has been conventionally avoided from the viewpoint of radiation resistance, suppresses the generation of defect absorption due to the irradiation of radiation caused by P. It has been found that radiation resistance is improved.

  The Ge content of the core part is preferably in the range of 0.5% by mass or more and 12.0% by mass or less. The lower limit of the Ge content is more preferably 1.0% by mass or more, still more preferably 2.3% by mass or more, and particularly preferably 3.2% by mass or more. The upper limit of the Ge content is more preferably 10% by mass or less, still more preferably 9.0% by mass or less, particularly preferably 8.6% by mass or less, still more preferably 6.0% by mass or less, and most preferably It is 5.0 mass% or less. If the Ge content is too low, it may be difficult to sufficiently improve the radiation resistance. On the other hand, if the Ge content is too large, the effect of improving the radiation resistance is saturated and the NA (numerical aperture) may be too large.

Ce has the effect of improving radiation resistance together with the above Ge.
The Ce content in the core part is preferably 0.12% by mass or less, particularly preferably in the range of 0.08% by mass to 0.12% by mass. By setting the Ce content in the above range, the radiation resistance can be improved more reliably.

Al, together with the above-mentioned P, coordinates around Er and increases the distance between Er, thereby suppressing the occurrence of Er clustering. Further, Al has an effect of leveling the amplification gain and an effect of reducing the NA of the core portion by co-adding with P.
The Al content of the core part is a mass ratio Al / P of Al and P, and is preferably less than 1.0. If the Al content is excessively large, defect absorption due to Al is likely to occur due to irradiation of radiation, and radiation resistance may be lowered. Generation of Er clustering can be further suppressed, and the NA of the core portion can be further reduced.

B has an action of reducing the NA of the core without deteriorating the radiation resistance. From the viewpoint of reducing the NA of the core, B can substitute for Al. Therefore, the amount of Al added can be reduced by adding B.
The content of B in the core part is preferably 0.6% by mass or less, particularly preferably in the range of 0.1% by mass to 0.6% by mass. If the content of B is excessively large, it is difficult to add both B and rare earth elements at a high concentration when producing a rare earth element-doped optical fiber preform (preform) by the MCVD method. When the element content is reduced, the effect of adding rare earth elements may be reduced. If the B content is too large, the difference in the linear expansion coefficient between the core portion and the cladding portion of the rare earth element-doped optical fiber preform becomes large during the production of the rare earth element doped optical fiber, and the preform is cracked. There is a possibility. Further, when the B content is less than 0.1% by mass, the effect of reducing the NA of the core by adding B may be reduced.

  In the rare earth element-doped optical fiber of the present embodiment, the material of the cladding part is not particularly limited as long as the refractive index is lower than that of the core part. For example, silica (quartz glass) can be used as the material of the clad portion.

  Although the optical fiber of this embodiment is not specifically limited, The diameter of a cladding part may be the range of 50 micrometers or more and 400 micrometers or less. Although the diameter of a core part is not specifically limited, The range of 3 micrometers or more and 110 micrometers or less may be sufficient.

Next, a method for manufacturing the rare earth element-doped optical fiber of the present embodiment will be described.
The rare earth element-added optical fiber of the present embodiment includes, for example, a base material manufacturing step for manufacturing a rare earth element-added optical fiber preform (preform) having a core portion and a clad portion covering the periphery of the core portion, and a rare earth element And drawing a rare earth element-doped optical fiber by drawing an element-doped optical fiber preform.

(Base material production process)
In the base material manufacturing step, a core forming portion including a silica composition including Er, Yb, P, and Ge, and further including Ce, Al, and B as necessary, and a clad forming portion that covers the periphery of the core forming portion; A rare earth element-doped optical fiber preform having the above is prepared. An MCVD method (Modified Chemical Vapor Deposition Method) can be used as a method for manufacturing the rare earth element-doped optical fiber preform. Specifically, in a quartz tube, a silica source (for example, SiCl ₄ ), an Er source (for example, Er (DPM) ₃ ), a Yb source (for example, Yb (DPM) ₃ ), a P source (for example, POCl ₃ ). While supplying a source gas including a Ge source (for example, GeCl ₄ ), a Ce source (for example, Ce (DPM) ₄ ), an Al source (for example, AlCl ₃ ), a B source (for example, BCl ₃ ), and oxygen, The quartz tube is heated with an oxyhydrogen burner. At this time, the amount of Er, Yb, P, Ce, Al, and B contained in the core portion can be adjusted by adjusting the type and composition of the source gas. In this way, soot made of glass composition particles containing Er, Yb, P, Ce, Al, and B is deposited on the quartz tube. Next, the quartz tube is heated with an oxyhydrogen burner, so that the soot becomes a transparent glass layer. Finally, the supply of the source gas is stopped, the quartz tube is heated with an oxyhydrogen burner, the quartz tube is softened, and the hollow portion is crushed. Thereby, a rare earth element-added optical fiber preform having a core forming portion including a silica composition containing Er, Yb, P, Ge, Ce, Al, and B and a clad forming portion covering the periphery of the core forming portion. can get.

  In addition to the MCVD method described above, various rare earth element-added optical fiber preform production methods such as an OVD method (Outside Vapor Deposition Method) and a VAD method are commonly used as an optical fiber preform production method. (Vapor phase Axial Deposition Method) can be used.

(Drawing process)
In the drawing process, the rare earth element-added optical fiber preform produced in the preform production process is heated and melted, and the melted rare earth element-added optical fiber preform is drawn into a string and cooled. As a method for drawing the rare earth element-doped optical fiber preform into a thread shape, various methods generally used in the production of optical fibers can be used.

  The obtained rare earth element-doped optical fiber can be used by coating the outer periphery of the cladding with a protective resin. As a method of coating the outer periphery of the clad portion with a protective resin, various methods generally used in the production of optical fibers can be used.

  According to the rare earth element-doped optical fiber of the present embodiment configured as described above, the core portion contains Er, Yb, P, and Ge. Therefore, even if the Er content is increased, Er clustering is performed. Is difficult to occur, has high radiation resistance, and is less likely to reduce gain even when used in an environment where radiation is present.

  A method for improving the radiation resistance of a rare earth element-doped optical fiber according to the present embodiment includes a core portion and a cladding portion that covers the periphery of the core portion, and the core portion includes a rare earth element containing Er, Yb, and P. This is a method for improving the radiation resistance of the doped optical fiber. In this embodiment, Ge is added to this core part. If necessary, Ce, Al, and B may be further added to the core part.

  The method for improving the radiation resistance of the rare earth element-doped optical fiber of the present embodiment is specifically a method in which Ge is contained in the core forming portion when the base material of the rare earth element doped optical fiber is manufactured. The amounts of Er, Yb, P, Ce, Al, and B contained in the core portion of the optical fiber obtained by using the method for improving the radiation resistance of the rare earth element-doped optical fiber of the present embodiment are as described above. is there.

  According to the method for improving the radiation resistance of the rare earth element-doped optical fiber of the present embodiment, the core portion adds Ge to the core portion of the optical fiber containing Er, Yb, and P. Generation of defect absorption due to irradiation can be suppressed, thereby improving the radiation resistance of the rare earth-doped optical fiber.

  Below, the effect of this invention is demonstrated by an Example.

[Example 1]
(Preparation of rare earth element-doped optical fiber preform)
By the MCVD method, the core part has an Er content of 0.12% by mass, a Yb content of 0.69% by mass, a P content of 9.95% by mass, and a Ge content of 4.0% by mass. A rare earth element-doped optical fiber preform (diameter: 13 mm) made of a material and having a clad portion made of silica glass was produced.

(Fabrication of optical fiber)
The rare earth element-doped optical fiber preform was drawn to produce a rare earth element doped optical fiber. The manufactured rare earth element-doped optical fiber was a multimode optical fiber (MMF) having a cladding portion diameter of 125 μm and a core portion diameter of 35 μm.

[Examples 2 to 23, Comparative Example 1]
(Preparation of rare earth element-doped optical fiber preform)
A rare earth element-doped optical fiber preform was produced in the same manner as in Example 1 except that the composition of the core was changed to the composition shown in Tables 1 and 2 below. In Tables 1 and 2, as the composition of the core part, Er content%, Yb content, P content, Ge content, Ce content, Al content, B content, Yb / Er mass ratio, P / Er mass ratio and Al / Er mass ratio were shown.

(Preparation of rare earth element-doped optical fiber preform)
In Examples 6, 8, 10, 11, 12, 13, 18, 19, 21, 22, 23 and Comparative Example 1, using the obtained rare earth element-doped optical fiber preform, Tables 1 and 2 below A rare earth-doped optical fiber having the structure shown was manufactured. In Example 6, Example 21, Example 22, and Example 10 and Example 23, rare earth element-doped optical fibers were manufactured using the same rare earth element-doped optical fiber preform. In Tables 1 and 2, MMF is a multimode type optical fiber, SMF is a single mode type optical fiber, DCF is a double clad type optical fiber, and 2LP-DCF is 2LP of LP01 mode and LP11 mode. It means a double clad optical fiber that propagates in a mode.
In SMF, DCF, and 2LP-DCF, after adding silica glass (cladding glass) to the outer peripheral portion of the rare earth element-added optical fiber preform by a jacket method (also called a rod-in-tube method), the core diameters are as shown in Tables 1 and 2 below. It was produced by drawing so that the diameter of the clad part was 125 μm.

  The obtained rare earth element-doped optical fiber was covered with a first resin layer, and then the first resin layer was covered with a second resin layer. The second resin layer was coated so that the outer diameter was 250 μm. In MMF and SMF, a resin having a refractive index higher than that of silica glass (cladding portion) was used as a material for the first resin layer on the rare earth element-doped optical fiber side. In DCF and 2LP-DCF, a resin having a lower refractive index than silica glass is used as a material for the first resin layer, and a resin having a higher refractive index than silica glass (cladding portion) is used as a material for the second resin layer. .

[Evaluation]
Using a rare earth element-doped optical fiber preform, the concentration distribution of the additive element and the X-ray resistance were measured. Further, γ-ray resistance was measured using a rare earth element-doped optical fiber. The measuring method is shown below.

(Concentration distribution of additive elements in rare earth element-doped optical fiber preform)
The rare earth element-doped optical fiber preform was cut in the radial direction. The concentration of the additive element was linearly analyzed using EPMA (electron beam probe microanalyzer) along the center line of the cut surface of the obtained cut piece. The measurement conditions for EPMA are shown below.
<Measurement conditions of EPMA>
Acceleration voltage: 15.0kV
Irradiation current: 1.17 × 10 ⁻⁷ A
Beam shape: circle
Probe diameter: 50 μm
Number of measurement points: 200
Scan width: 1cm
Measurement time: 2 sec

  The results obtained for the rare earth element-doped optical fiber preforms produced in Examples 1 to 20 are shown in FIGS. 1 to 20, the horizontal axis indicates the measurement position from the center of the base material, and “0” indicates the center of the core portion of the base material. The vertical axis represents the concentration of each additive element contained in the base material. It was confirmed that the average concentration of each additive element of Examples 1 to 20 calculated from FIGS. 1 to 20 coincided with the amount of additive element in the core part of Examples 1 to 20 described in Table 1. .

(X-ray resistance)
The rare earth element-doped optical fiber preform was cut in the radial direction. About the obtained cut piece, the light absorption coefficient of the core part of a cut surface was measured on condition of the following.
<Measurement conditions for light absorption coefficient>
Wavelength range: 200-1600nm
Resolution: 0.5nm

  Subsequently, the core part of the cut surface of the cut piece was irradiated with X-rays having a wavelength of 0.71 mm (Mo) at an output of 17.5 keV for 100 minutes. About the cut piece after X-ray irradiation, the light absorption coefficient of the core part of a cut surface was measured again. Then, a value obtained by subtracting the light absorption coefficient of the core part before X-ray irradiation from the light absorption coefficient of the core part after X-ray irradiation was calculated as the absorption coefficient increase amount. In the rare earth element-doped optical fiber preform produced in Comparative Example 1, it was clear that the core after X-ray irradiation was colored reddish purple, and the light absorption coefficient was significantly increased. The coefficient was not remeasured.

  The results obtained for the rare earth element-doped optical fiber preforms produced in Examples 1 to 10 are shown in FIG. 21, and the results obtained for the rare earth element doped optical fiber preforms produced in Examples 1 to 10 are shown in FIG. . Absorption of light having wavelengths of 240 nm, 400 nm, 510 nm, and 570 nm is induced defect absorption by P-OHC (phosphorus oxygen hole center). From the results of FIGS. 21 and 22, it can be seen that the core portion of the rare earth element-doped optical fiber after X-ray irradiation increases the light absorption by P-OHC. Tables 1 and 2 show the increase in absorption coefficient of light having a wavelength of 550 nm as X-ray resistance.

(Gamma ray resistance)
For the rare earth element-doped optical fibers produced in Examples 1, 6, 8, 10, 11, 12, 13, 18, 19, 21, 22, 23 and Comparative Example 1, the horizontal axis is the wavelength of light, and the vertical axis is The light loss spectrum as the light absorption loss was measured by the following method.
<Measurement method of light loss spectrum>
The loss spectrum was measured by the cutback method. White light was incident on a fiber to be measured having a length L ₀ [m], and a transmitted light spectrum was measured using an optical spectrum analyzer. The optical power at this time was P ₀ [dBm]. Next, the length of the fiber to be measured was cut back to L ₁ [m], and the transmitted light spectrum of the fiber to be measured after cut back was measured. The optical power at this time was P ₁ [dBm]. L ₀ was about 10 m, and L ₁ was about 2 m. Absorption loss [dB / m] _is determined by _{(P 1 -P 0) / (} L 0 -L 1).

Next, the rare earth element-doped optical fiber was irradiated with γ rays of 1000 Gy (corresponding to standing in a geostationary orbit for 10 years) using a cobalt 60 γ-ray irradiation device. The light loss spectrum of the rare earth element-doped optical fiber after γ-ray irradiation was remeasured. Then, a value obtained by subtracting the light loss spectrum before γ-ray irradiation from the light loss spectrum of the rare earth element-doped optical fiber after γ-ray irradiation was calculated as an increase in absorption loss. Convert the wavelength (nm) of the loss spectrum of light into photon energy (eV), create a graph with the horizontal axis as photon energy (eV) and the vertical axis plotting the increase in absorption loss. Using the obtained data, Gaussian fitting was performed to obtain an approximate curve. Gaussian fitting was performed using the parameters described in the following literature.
“DL Griscom, EJ Friebele, KJ Long and JW Fleming,“ Fundamental defect centers in glass: Electron spin resonance and optical absorption studies of irradiated phosphorus-doped silica glass and optical fibers, ”Jounal of Applied Physics, vol. 54, no. 7, pp. 3743-3762, 1983. ''

  The results obtained for the rare earth element-doped optical fibers produced in Examples 1, 6, 8, 10 and Comparative Example 1 are shown in FIG. 23, and Examples 11, 12, 13, 18, 19, 21, 22, 23 and Comparative Example are compared. The results obtained for the rare earth element-doped optical fiber produced in Example 1 are shown in FIG. Absorption of light with a wavelength of 1570 nm is induced defect absorption by phosphorus (P1). From the results of FIGS. 23 and 24, it can be seen that the rare earth element-doped optical fiber after γ-ray irradiation increases the light absorption by P1. Tables 1 and 2 show the increase in absorption loss of light having a wavelength of 1570 nm as γ-ray resistance.

  In Comparative Example 1 in which Ge was not added to the core portion, the light absorption coefficient after X-ray irradiation and the light absorption loss after γ-ray irradiation were large. This is presumably because the induced defect absorption by POHC and P1 was increased by the irradiation of radiation.

  On the other hand, in Examples 1 to 23 in which Ge was added to the core portion, the light absorption coefficient after X-ray irradiation and the light absorption loss after γ-ray irradiation were small. That is, from the results of Examples 1 to 23, it was confirmed that the radiation resistance of the rare-earth-doped optical fiber is improved by adding Ge. Moreover, it was confirmed from the results of Examples 7 and 8 that radiation resistance is further improved by adding Ce together with Ge. Further, from the results of Examples 9, 10, 11 to 20, and 23, it was confirmed that Ge is effective for a rare earth element-doped optical fiber containing P and Al.

  FIG. 25 shows the relationship between the Ge addition concentration, the X-ray resistance, and the γ-ray resistance of the core portion of the rare earth element-doped optical fiber. The horizontal axis of FIG. 25 shows the Ge addition concentration of the core part, and the RIA of P-OHC (X-ray) (550 nm) on the left vertical axis shows the increase in the absorption coefficient of light having a wavelength of 550 nm after X-ray irradiation, RIA of P1 (Ganma-ray) (1570 nm) on the right vertical axis indicates an increase in absorption loss of light having a wavelength of 1570 nm after γ-ray irradiation. In addition, the white circle and black circle P-Ge indicates the measurement results of the optical fiber and the rare earth element-doped optical fiber containing Yb and Er, P, and Ge. The white triangle and the black triangle P-Ge-Ce indicate Yb and Measurement results of rare earth element-doped optical fiber base material containing Er, P, Ge, and Ce and optical fiber, white square and black square P-Ge-Al are rare earth elements containing Yb, Er, P, Ge, and Al. The measurement results of the doped optical fiber preform and the optical fiber are shown as white rhombus and black rhombus P-Ge-Al-B: rare earth element-doped optical fiber preform and light containing Yb, Er, P, Ge, Al, and B The measurement result of a fiber is shown. White circles, white triangles, white squares, and white rhombuses indicate the increase in the absorption coefficient of light having a wavelength of 550 nm after X-ray irradiation, and black circles, black triangles, black squares, and black rhombuses indicate a wavelength of 1570 nm after γ-ray irradiation. Shows the amount of increase in light absorption loss.

The following can be understood from the graph of FIG.
(1) From the measurement results of rare earth element-doped optical fiber preforms and optical fibers (white circles and black circles) containing Yb, Er, P and Ge, X-ray resistance and γ-ray resistance are proportional to the Ge concentration. And improve.
(2) The effect of the above (1) tends to saturate as the Ge concentration increases.
(3) From the measurement results of rare earth element-doped optical fiber preforms and optical fibers (white triangles and black triangles) containing Yb, Er, P, Ge, and Ce, even if the Ge addition concentration is the same, Ce is shared. By adding, X-ray resistance and γ-ray resistance are improved.
(4) From the measurement results of rare earth element-doped optical fiber preforms and optical fibers (white squares and black squares) containing Yb, Er, P, Ge, and Al, Al is within a range where Al / P is less than 1.0. The co-doped rare earth element-doped optical fiber exhibits X-ray resistance and γ-ray resistance equivalent to those of rare earth element-doped optical fibers (white circles and black circles) containing Yb, Er, P, and Ge.
(5) From the measurement results of rare earth element-doped optical fiber base materials containing Yb, Er, P, Ge, Al, and B and optical fibers (white rhombus and black rhombus), B was co-doped to reduce the Al concentration. The rare earth element-doped optical fiber exhibits X-ray resistance and γ-ray resistance equivalent to those of the rare earth element-doped optical fiber preform and optical fiber (white circle and black circle) containing Yb, Er, P, and Ge.

  From the above results, according to the present invention, a novel rare earth element-doped light that has high radiation resistance and does not easily reduce gain even when used in an environment where radiation exists, even though the core portion contains rare earth elements and P. It was confirmed that fiber could be provided. Moreover, according to this invention, it was confirmed that the novel method of improving the radiation resistance of the rare earth element addition optical fiber which contains rare earth elements and P in a core part can be provided.

Claims (7)

  A rare earth element-doped optical fiber having a core part and a clad part covering the periphery of the core part, wherein the core part contains erbium, ytterbium, phosphorus, and germanium.   The erbium content is 0.05% by mass or more, the phosphorus content is 18 or more and 360 or less in the mass ratio P / Er of the phosphorus and the erbium, and the germanium content is 0.00. The rare earth element-doped optical fiber according to claim 1, wherein the content is 5% by mass or more and 12.0% by mass or less.   The rare earth element-doped optical fiber according to claim 1 or 2, wherein a content of the ytterbium is 4 or more and 50 or less in a mass ratio Yb / Er of the ytterbium and the erbium.   The rare earth element-doped optical fiber according to any one of claims 1 to 3, wherein the core portion includes cerium, and the content of the cerium is 0.12% by mass or less.   The rare earth element according to any one of claims 1 to 4, wherein the core portion includes aluminum, and the content of the aluminum is less than 1.0 in terms of a mass ratio Al / P between the aluminum and the phosphorus. Additive optical fiber.   The rare earth element-doped optical fiber according to any one of claims 1 to 5, wherein the core portion contains boron, and the boron content is 0.6 mass% or less. A core part and a cladding part covering the periphery of the core part, wherein the core part is a method for improving the radiation resistance of a rare earth element-doped optical fiber containing erbium, ytterbium and phosphorus,
A method for improving the radiation resistance of a rare earth element-doped optical fiber, wherein germanium is added to the core portion.

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