DE2818152A1 - LARGE NUMERICAL APERTURE LIGHT GUIDE AND METHOD FOR ITS MANUFACTURING - Google Patents

Description

A.R. Asam 8-6

Large numerical aperture light guide and method for its manufacture

As the numerical aperture of a light guide, the sine of half of the opening angle of one provided with a sheath is used Called light guide. If n. The refractive index of the fiber optic core and η is the refractive index of the clad, then gives

2 2 1/2 the numerical aperture as Sin θ = (n ₁ - η). The amount of light entering the light guide is greater, the larger its numerical aperture is. Since the numerical aperture is proportional to the difference between the refractive index of the core and the clad, attempts have already been made to increase this difference by increasing the refractive index of the core and decreasing the refractive index of the clad.

In the case of light guides made entirely of glass, the best light guides, i.e. the light guides with the lowest attenuation, are achieved by either 5 doped with a material with a higher refractive index or pure quartz is used to increase the refractive index or quartz is used as a sheath, to which a substance is added to lower the refractive index. The numerical The aperture of light guides made entirely of glass is determined by the amount of material that increases the refractive index the quartz can be added before the thermal expansion properties of the entire light guide material impaired v / earth. Will the quartz too much

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of the refractive index-increasing material is added, then the thermal expansion coefficient of the increases doped quartz core such that a mismatch between the doped quartz core and the undoped pure quartz shell entry. The different coefficients of thermal expansion between core and shell mean that the The preform bursts on cooling. The amount of doping material that the core uses to increase the numerical Aperture that can be added is therefore limited by the difference in the coefficient of thermal expansion from Core and shell. The measure of lowering the refractive index of the quartz shell by adding a dopant, also causes a thermal mismatch between shell and core, so that the shell only a limited one Amount of doping material can be added.

The object on which the invention is based is now to create a light guide that has a highly doped Quartz core and has a large numerical aperture without causing a thermal mismatch between the core and the sheath of the light guide enters.

This object is achieved according to the invention in that the Core made of a glass material with a refractive index of at least 1.5 and the shell made of a resin material with has a refractive index less than 1.5.

Further advantageous details of the invention are contained in claims 2 to 9. It is shown below using a Embodiment described with reference to Figures 1 to 7. Show it:

Fig.1 the characteristic curve of the course of the numerical

Aperture as a function of the difference in refractive index between core and shell of the light guide,

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Fig. 2 the characteristic of the refractive index curve in

Dependence on the germanium content in the fiber optic core,

3 shows the characteristic of the refractive index curve in Dependence on the content of boron oxide in the light guide

core,

Fig. 4 is a perspective view of a removable

Mold for the production of the fiber optic core material,

5 shows in perspective view the shape of Fig.4 ^w ith an inner layer of highly pure light guide

material,

Fig. 6 partially in sectional view one with the form from Fig. 5 usable glass lathe,

6a shows the cross section of the core 15 produced with the mold Material,

7 shows the cross section of the core material according to the Ko1labieren, and

7a shows the cross section of the light guide.

A large number of light guides with a doped quartz core were produced using the vapor deposition method produced, the concentration of the doping material

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was constantly increased to the largest possible numerical aperture to determine which can be achieved with the usual fiber optic manufacturing processes. The light guides were in the Way manufactured that little by little a lot of germanium silicate deposited on the inner surface of a quartz tube, the thus coated support tube collapses and the preform produced in this way was drawn out to form the light guide.

Since the theoretical value of the refractive index of pure germanium reaches approximately 1.6, a Series of light guides the germanium content in the germanium silicate increased from time to time to the practical limit of what can be achieved To determine the refractive index. Using very careful heating and tempering procedures, light guides were made produced with doped germanium silicate cores and quartz shells, the numerical aperture of which was about 0.24. The index of refraction of the doped quartz core was measured to be about 1.5 in these light guides and the refractive index of the clad was measured about 1.46.

As Pig.1 shows, the numerical aperture is the Difference between the calculation indices of the core (n ..) and proportional to the envelope (s). Because of the differences in the thermal properties of the doped quartz with increasing Germanium content, the refractive index of the doped core reached about 1.5 before the different expansion properties cracked the preform on cooling after the coating process. The course of the Refractive index in the case of quartz doped with germanium is shown in FIG.

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The theoretical value of 1.6 for almost pure germanium cannot be achieved with quartz because of its thermal expansion properties of the enveloped core adversely affect the drawn light guide when the concentration of the dopant reaches about 20 to 40% germanium.

Since the numerical aperture is proportional to the difference in the refractive indices of the core and cladding material, some Efforts have been made to lower the refractive index of the clad. 3 shows the course of the refractive index of doped quartz with increasing boron oxide content.

As can be seen from FIG. 3, the refractive index takes with it Boron oxide-doped quartz initially decreases as the proportion of boron oxide increases, only to increase again with heavier doping. By doping quartz with boron oxide, cladding materials with a refractive index of 1.45 can be achieved. If you are for the core is a quartz doped with germanium with a refractive index of 1.5 and for the shell a quartz doped with boron oxide Using quartz with a refractive index of 1.45, a light guide with a numerical aperture of 0.36 is obtained.

Up to now, however, it has not been possible to use the numerical aperture in a light guide with a doped core and a doped cladding to raise above 0.4. With a very carefully controlled separation and careful handling of the not yet When the preform collapsed, the value of the numerical aperture had to be increased to a little more than 0.36, but the manufacturing effort required for coating and heat treatment made further Increases in the numerical aperture are uneconomically expensive.

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One of the proposed according to the invention for the shell Materials which have a refractive index of about 1.41 and in which there are no difficulties due to the expansion properties of the doped quartz core is a high-purity silicone resin based on dimethylsiloxane. This material has a high permeability for optical communication and good adhesion to the doped quartz core without any mismatching phenomenon Reason for different thermal expansion coefficients. The coating of a doped quartz core with high-purity silicone resin resulted in a light guide with a numerical Aperture of 0.43 and mechanical resistance after cooling.

The high concentration of pure germanium silicate glass was created by chemical deposition of quartz and germanium reached from the vapor phase inside a quartz tube. The one with an inner layer of germanium silicate glass Quartz tube was then heated to the collapse temperature to produce a rod that consists of a germanium silicate core and a shell that is heavily enriched with germanium Possesses quartz glass.

The outer quartz shell was then removed by grinding until only the inner core made of germanium silicate glass was left was left. The germanium silicate rod was then clamped in a drawing device, heated and turned into fibers drawn. During the draw, the fiber was passed through a container of high purity dimethylsiloxane, whereby the Surface of the germanium silicate fiber with a uniform

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Silicone cover was provided. The germanium content in germanium silicate glass is only limited by the different thermal expansion of the doped core and quartz tube after coating.

Know preforms made of highly doped quartz through coating of high-purity glass from the vapor phase using a plasma or oxyhydrogen gas flame. You can Let the glass grow into a glass blank, then pull it out into fibers and coat it with silicone resin.

Highly doped quartz glasses can easily be deposited in a removable carbon tube by deposition from the vapor phase and then collapsing the tube to the rod.

The carbon tube is easily removed by that it is burned away by heating it to the ignition temperature, so that after cooling there is no thermal mismatch there is more.

When manufacturing the new light guide, there are no different expansion coefficients of the materials difficulties based more on. Glass highly doped with germanium can easily be made and one from it manufactured fiber can just as easily be provided with the sheath without any difficulties thereafter.

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The use of the removable carbon tube as a substrate allows high germanium to be made doped glass with a high refractive index of 1.6, as shown in Fig. 2 as the maximum achievable. That Silicone resin used as the cover is excellent in flexibility and strongly adheres to the surface of the germanium-containing glass without any impairment of the same.

By using a removable carbon tube as a deposition substrate for the core material, concentrations more than 70% germanium is possible, which gives a refractive index of about 1.55. Together with the outer shell made of silicone resin, this results in a numerical aperture of the light guide of over 0.6.

For the use of the light guide in shorter lengths, whereby it does not have to have an exceptionally high strength, is to realize a light guide with a core made of pure germanium and a silicone cover, its numerical aperture is over 0.8. Short pieces of such a light guide can also be used to emit light Diodes on fiber optics for transmission over long distances to be coupled, which themselves have a smaller numerical aperture.

Other materials used as doping materials in the manufacture of core materials with a high refractive index Can be used are the oxides of zinc, phosphorus, titanium, aluminum and zirconium. These substances can be added in high concentration to the quartz to produce appropriate glasses.

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A removable carbon support 13 for the deposition of highly doped quartz core material is shown in Fig. 4. Such a carbon carrier 13 is shown in FIG a glass lathe 19 within a special water-cooled tube 10 with a cooling water inlet 2 and outlet used. The heating is done by high frequency induction coils 15, which comprise the water-cooled pipe 10. The carbon tube 13 is inserted into the lathe 19 in such a way that that between the inner surface of the water-cooled tube 10 and the surface of the carbon tube 13 is an elongated, annular gap remains through which a constant flow of inert gas is sent from the nozzles 24 and 24 '. This gas atmosphere prevents the heating and oxidation of the carbon tube 13 during its inner coating.

The substances causing the deposition from the vapor phase are fed to the carbon tube 13 from the tube end 20 by means of the Feed pipe 21 supplied, which the germanium chloride and brings silicon tetrachloride gases along with the required amount of oxygen. The chemical deposition from the vapor phase takes place in the usual manner in such a way that the gas mixture supplied by the induction coil 15 is heated and germanium silicate glass is deposited from it on the inner surface of the tube 13.

The coated pipe 13 shows Fig.5 after a layer of germanium silicate glass has been deposited on its inner surface. The carbon tube 13 is after the coating process removed by cutting off the flow of inert gas, whereafter the carbon tube heats up and burns down. The remaining germanium silicate pipe that

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Fig.6a shows, then becomes a stick by heating collapses, as shown in Fig. 7. The Ftab 11 made of germanium silicate glass is clamped in a drawing device, heated and drawn into fibers. The core fiber 11 is thereafter provided with a layer 12 of pure silicone resin, whereby a light guide 14 for optical communication with the core 11 and the IUUIe 12 arises.

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Claims (9)

Patent attorney Dipl.-Phys. Leo Thul Kurz Str. 8 7 Stuttgart 30 A.R. Asam-M.S. Maklad 8-6 INTERNATIONAL STANDARD ELECTRIC CORPORATION, NEW YORK Claims 1. Light guide with low attenuation and large numerical aperture, characterized in that the core consists of a glass material with a refractive index of at least 1.5 and the shell consists of a resin material with a refractive index of less than 1.5. 2. Light guide according to claim 1, characterized in that the core consists of doped quartz (SiO ₂ ). 3. Light guide according to claim 1 and 2, characterized in that the dopant is germanium, phosphorus pentoxide, titanium, zinc oxide or aluminum oxide. 4. Light guide according to claim 1, characterized in that the core consists of germanium, phosphorus pentoxide, titanium, zinc oxide or aluminum oxide. 5. Light guide according to claim 1 and one of claims 2 to 4, characterized in that the resin material contains silicone. Bo / Sch
04/21/1978 809846/0679 A.R. Asam 8-6 6. Light guide according to claim 5, characterized in that the resin material is based on dimethylsiloxane. 7. A method for producing a light guide with low attenuation and a large numerical aperture, characterized in that for the production of the core quartz is doped with a material which has a higher refractive index than quartz, the doped quartz is drawn to the light guide and the light guide then with a Silicone resin, which has a lower refractive index than quartz, is encased. 8. The method according to claim 8, characterized in that for the production of the core germanium and quartz are deposited on a tubular support, and the resulting tube is collapsed to form the preform. 9. The method according to claim 8, characterized in that oxides of germanium, phosphorus, titanium, zinc and aluminum are used as doping material. 809846/0679