NL193330C - Optical waveguide and method for its manufacture. - Google Patents

Description

1 193330

Optical waveguide and method for its manufacture

The invention relates to an optical waveguide formed by a high temperature drawing operation from a preform composed of a core part, a cladding part enclosing the core part 5 and a jacket part.

The invention further relates to a method of manufacturing such an optical waveguide, wherein a preform composed of a core part, a cladding part enclosing the core part and a sheath part is subjected to a high temperature drawing operation.

Such an optical waveguide and such a method are known from US patent 3,982,916. This known waveguide and method is based on a preform with a core part that is built up of four sectors, each sector being bounded by two adjacent sectors, which form a pair of opposite sectors of material of equal composition and the composition of the material of the sector concerned differs from the composition of the material of the adjacent sectors. This construction of the preform ensures that the course of the refractive index in two mutually perpendicular directions perpendicular to the axis of the waveguide is different.

Optical waveguides, which can transmit power with only one polarization direction, are desirable for use in integrated optical devices. The known optical waveguide is not capable of this. The object of the invention is to provide an optical waveguide which is able to do this, as well as to provide a method for manufacturing such an optical waveguide.

According to the invention, the stated object is achieved with an optical waveguide, the structure of the preform being chosen such that birefringence in the waveguide due to difference in mechanical stresses along two mutually perpendicular directions perpendicular to the axis of the waveguide is greater than 5 x 105 and that the thickness of the sheath of the waveguide in one of the mutually perpendicular directions is considerably greater than in the other perpendicular direction.

These measures are based on the recognition that orthogonally polarized waves are more efficiently decoupled in a waveguide manufactured in such a way that it deliberately increases mechanical stress induced by shape change as a result of shape change. This amount is achieved by providing such a geometric and material deviation in the circular symmetry in the molding from which the optical fiber is drawn that the resulting mechanical stress-induced birefringence Δη is advantageously greater than 5 x 10 5. The resulting beat period L for such a waveguide is less than 20 mm at a wavelength of 1 μm and less than 10 mm at 0.5 µm, where L = 2η / Δβ, and ΔΒ is the difference in propulsion constants for the two perpendicular directions of the wave polarization of interest.

It is noted that from the publication Electronics Letters 10 (1974, 10, 31) 22, 449/450 an optical waveguide with a core of a monocrystalline material with birefringence is known. However, there is no question of birefringence due to difference in mechanical stresses along two mutually perpendicular directions perpendicular to the axis of the waveguide. The known waveguide therefore does not seem capable of transmitting power with only one polarization direction.

The method according to the invention for manufacturing the optical waveguide according to the invention has various embodiments.

In a first embodiment, a preform is used, in which the thickness of the jacket egg in one of two mutually perpendicular directions is considerably larger than in the other perpendicular direction, wherein the ratio of the radius c of the covering part with respect to the thickness a of the jacket egg in the direction in which this thickness is greatest is less than 0.5 and the ratio of the smaller thickness b of the jacket egg in the direction perpendicular to the direction of the greatest thickness relative to that greatest thickness a is equal to or less than 0.1.

In another embodiment, a preform is used, in which a jacket egg of uniform thickness 50 is formed on the cladding portion, which jacket egg includes two diametrically opposed longitudinally extending slots along the preform.

In yet another embodiment, wherein the preform is obtained in the manner known from U.S. Pat. No. 3,982,916 by depositing the cladding portion and the core portion in the form of layers on the inner surface of a tubular body forming the jacket egg and the cavity of the 55 tubular body with the deposited layers to collapse at high temperature, a tubular body of such predetermined shape is used that the thickness of the wall of the tubular body for a first direction perpendicular to the axis of the tubular body noticeably different from the wall thickness 193330 for a second direction perpendicular to the first direction and the axis of the tubular body.

In the latter embodiment, materials are preferably used for manufacturing the preform such that the melting point of the cladding part is lower than the melting point of the tubular body forming the cladding part. In cooling the preform, therefore, mechanical stresses are induced which induce the intended birefringence in the final waveguide.

The invention is elucidated with reference to the drawing.

Herein resp. Figures 1 and 2 show two planar optical waveguides, Figure 3 shows a cylindrical preform for an optical waveguide with an inner core surrounded by a cladding, Figure 4 shows a three-layer preform for an optical waveguide, Figure 5 shows the preform according to Figure 4 after diametrically opposed portions of the outermost layer have been removed, Figure 6 is a section through an optical waveguide drawn from the preform of Figure 5 for one polarization direction, Figures 7 and 8 are a section through other embodiments of a three-layer preform for an optical waveguide for one polarization direction, Fig. 9 is a sectional view of an embodiment of a two-layer preform for an optical waveguide for one polarization direction, Fig. 10 is a cross-section of a substrate tube for a preform for an optical waveguide for one polarization direction, figure 11 shows a cross-section of a piece from d the substrate tube according to figure 10 obtained before the preform is fused into a rod, figure 12 a cross section of an optical waveguide for one polarization direction obtained from the fused preform according to figure 11, figures 13 and 14 a section of other embodiments of the substrate tube for an optical waveguide preform for one polarization direction.

In Fig. 1, a flat waveguide 10 is shown, which consists of an inner dielectric core portion 11 and two outer dielectric layers 12 and 13, which are in contact with the major surfaces of the member 11. In order to guide waveguide primarily in the inner dielectric core portion 11, or the core region of the waveguide, the refractive index of the outer layers is less than that of the core portion 11.

Notwithstanding that the width w of the core is many times greater than the thickness t, such a waveguide is capable of propagating optical wave energy polarized in directions parallel to both transverse dimensions of the core region. In the absence of any external coupling mechanism, a beat length L can be defined in which energy is fully exchanged between the two orthogonally polarized waves, that is, the energy reappears in the same polarization after being completely transferred to the other polarization. For a single mode fiber, this length L is given as: L = 2π / Δβ (1), where ΔΒ represents the difference in propagation constants of the two orthogonally polarized waves. It will be clear that by increasing ΔΒ the beat length can be reduced. Since mechanical perturbations with a spatial periodicity, which is similar to the beat length, cause unwanted coupling from one polarization to another, the beat period is advantageously made smaller than the disturbance periodicity caused by the method of manufacture or by bending and twisting, which occurs when using the waveguide. For example, at a wavelength of 0.63 µm, a borosilicate fiber having a refractive index gradient with a 50 nominal circular geometry has a beat length greater than 10 cm. Mechanical disturbances of comparable length are not uncommon. As a result, the wave energy injected with one polarization and propagated through such a fiber tends to be subject to cross polarization. Known planar fibers tend to provide cross-polarized wave energy, despite the fact that the aspect ratio of the waveguide region can differ much from one. Polarization coupling is avoided by mechanical stress-induced refraction in the waveguide, such that ΔΒ increases sharply. The term "mechanical stress-induced birefringence" or "stress birefringence", as used herein, refers to the difference in major refractive indices generated by effecting a difference in mechanical stresses along mutually perpendicular directions in the waveguide region. For example, birefringence in the dielectric layer 11 can be induced if the coefficient of thermal expansion of the layer 11 is different from that of the outer layers 12 and 13. If so, the width of the core portion 11 will be different. than that of layers 12 and 13, as the fiber cools upon drawing. However, since the three layers are bonded together, they will all assume the same width, creating an internal stress in the core portion 11 in the w direction when the outer layers are sufficiently rigid. However, since such a voltage is not induced in the t direction, the consequence of this anisotropic voltage is to create a relatively large difference in wave energy propagation constants polarized along these two directions.

The magnitude of the difference in refractive indices Δη for the two polarization directions is proportional to the difference in mechanical stress in these two directions and is given by: Δη - (α0 - α,) ΔΤ (2) where α0 and α are the thermal coefficients of the outer and inner layers and ΔΤ 15 respectively is the difference between the operating temperature and the temperature at which the glass layers become rigid.

In order to provide an alternative waveguide structure, the plate structure of Figure 1 can be modified as shown in Figure 2 and include an inner core region 14 surrounded by an intermediate cladding 15 with less refractive index and an outer jacket 16. A waveguide of such structure can be easily manufactured by assemble individual glass slides or by well known sequential deposition techniques.

In order to achieve the desired large birefringence in the waveguide portion, which includes core 14 and cladding 15, the difference between the thermal expansion coefficients of the sheath material and the waveguide material is made large. In addition, the dimensions of the plate-shaped bodies should preferably meet the following inequalities: 25 (t1 + t3) c1 »t2c2 (3) and (w, + Wajc,« w 2c2 (4) in which c- and c2 are the modulus of elasticity of the sheath and of the waveguide material, c-, and c2 will be approximately equal, so that the inequalities given above are primarily geometric In some cases, as will be shown below, w, and w3 are equal to zero.

The voltage birefringence for the waveguide with the structure of Figure 2 is (Sy - Sx) = (c ^ - α2) ΔΤ (5) where Sy and Sx are the mechanical stresses induced along the y axis and x axis, respectively, and ΔΤ = Ta - Tb, where Ta is the ambient operating temperature and Tb is approximately equal to the "softening temperature" of the material, and o, and a2 are the coefficients of thermal expansion of the jacket and waveguide regions, respectively. an and a2 are independent of the temperature when estimates are made.

The voltage birefringence Δη is given by n3 ΔΠ + -2 (p „-p12) (α, -o ^ jAT (6) 40 where n represent the refractive index and p ^ and p12 the photoelastic constants of the waveguide material.

For example, a preform or molding to be used for the fabrication of a waveguide will include a jacket of pure silicon oxide as well as a coating and core made of borosilicate, germanic silicate or phosphorsilicate glass material, the core and coating being doped differently to achieve the desired difference in refractive index. In the following examples, the values of P1 and p12 for silica are used.

Example I

For a coating of Si02 with 5 mol% B203, the calculated Δη 1 x 10 "4, while n approximately 50 equals 1.5, (pn - p12) = 0.15, (α, -α2) = - 5 x 10'7 ° C'1 and ΔΤ «-850 ° C.

Example II

For a coating of Si02 with 25 mol% Ge02, the calculated Δη is 4 x 10'4, while n «1.5, (Pu - Pia) * 0.15, (α, -Oa) = -1.6 x 1Q-6 0C'1 and ΔΤ = -1000 ° C.

193 330 4

Example III

For a coating of Si02 with 12 mol% P2Os, the calculated Δη is 4 x 10-4, while n = 1.5, (Pn - P12) »0.15, (0 ^ -0½) = -1.4 x 10-6 ° σ1 and ΔΤ - -1200 ° C.

In each of the above examples, it is believed that core and coating have approximately the same thermal properties.

Once the operative mechanism has been recognized, the principles of mechanical stress-induced birefringence or stress birefringence can be applied to adapt conventional optical waveguides or fibers as well. For example, an optical fiber is drawn from a molding 20 of the type shown in Figure 3, comprising an inner core region 21 surrounded by an outer covering 22. Due to the circular symmetry, only very little stress-induced birefringence in a fiber drawn from such a molding. As a result, a deviation from the circular symmetry must be purposefully applied to enhance the voltage birefringence. More specifically, as a blank, the three-layer structure 30 of the type shown in Figure 4 is considered, comprising an inner core region 31 surrounded by an intermediate cladding layer 32 and an outer cladding layer 33. In one embodiment of the manufacturing method of a single polarization waveguide, diametrically opposed portions of the outer layer 33 are abraded or otherwise removed, leaving the molding in the shape shown in Figure 5, comprising a core 31, a coating 32 and a modified outer layer 33, parts 33 'and 33 "of which have been removed.

When such a modified molding is drawn, the surface tension changes its cross-section to the cross-section shown in Figure 6, which approximates the plate-shaped configuration of Figure 2. As in the embodiment of Figure 2, the outer sheath layer 33 produces a mechanical stress in the fiber in the y direction, which is much greater than the stress produced in the x direction. The ratio of the two stresses is related to the thicknesses a, b and c in the molding and the corresponding dimensions a ', b' and c 'in the resulting fiber.

Although any deviation from the circular symmetry will lead to a stress birefringence, it has been found that beat periods of less than 5 mm are achieved when the ratio of the radius c of the coating to the original thickness a is less than half, which means 30 | <0, 5 (7) and when the ratio of the reduced thickness b of the outermost layer to the original thickness a is equal to or less than one-tenth, that is | <0.1 (8) Figure 7 shows another embodiment of the molding for manufacturing a waveguide for one polarization direction. In this embodiment, diametrically opposed cuts 40 'and 40 "are provided in the outer layer 40 around the liner 41. A fiber, drawn from such a molding, was given the shape shown in FIG. 8.

In a third embodiment of the single polarization waveguide molding 40 shown in Figure 9, diametrically opposed annular segments 51 and 52 are provided on the cladding layer 50.

Which of the described moldings are used will depend on the nature of the blank. For example, some moldings, such as those doped with borosilicate, are made with three layers. Consequently, the method shown with reference to Figures 5 and 7 will be applicable. On the other hand, when starting from a two-layer molded part, the method according to figure 9 can be used.

Figure 10 shows an end view of a quartz substrate tube 60. The outside diameter is 7,010 to 7,087 mm. The inner diameter is 2.515 mm. Flat surfaces were sanded on the sides of the tube as shown, the distance between the flat surfaces being 6.477 50 mm. The substrate tube was then mounted in a conventional type device for depositing layers of chemicals on the inside of the substrate tube. (The device is essentially a modified lathe, in which the substrate tube is mounted in the usual supply position and a gas heater is mounted on the tool drive.) The interior of this substrate was cleaned with a conventional glass cleaner and distilled water and dried in a stream of nitrogen gas. After being set up in the 55 device, the tube was heated to 1025 ° C, with a mixture of 250 cc / min. oxygen and 750 cm3 / min. argon was guided by it.

5 193330

An outer coating layer was deposited by 4 hours and 12 min. 250 cc / min. oxygen, 50 cm3 / min. 3% silane in argon mixture, 16 cm3 / min. 1% diborane in argon and 750 cm3 / min. flowing argon at a temperature of 985 ° C. An inner coating layer was deposited by increasing the flow of diborane in argon to 26 cc / min for 48 min, while the other parameters were maintained at the original value 5.

A core layer was deposited at 27 min. 250 cc / min. oxygen, 25 cm3 / min. 3% silane in argon and 750 cm3 / min. run argon at 1060 ° C.

The molding thus formed is shown in Figure 11. The substrate 60 internally includes an outer clad layer 63, an inner clad layer 64 and a core layer 65. The whole was then compressed in one treatment to an outer diameter of 0.4724 mm and then drawn into a fiber by conventional means. The fiber had an outer diameter of 0.1168 mm.

During compression of the molding, the surface tension on the outer surface pulls the outer surface to a circular cross section, shown in Figure 12, the substrate 60 '15 having a circular outer surface and a non-circular inner surface, resulting from a deformation of the interior as response to the surface stresses on the outer surface. The coating 66 includes the material of both the coating layers 63 and 64. The correct shape will of course vary with the detailed parameters of the molding. The ellipticity of the coating 66 is exaggerated in Figure 12 for clarification. Generally, the coating substrate surface 20 is clearly elliptical in cross-section and the surface between the core 65 'and the coating 66 is circular in cross-section or has a very low degree of ellipticity. In some cases, the ellipticity of the core can be very different from that of the coating. This appears to depend on the relative melting points of the core and cladding glass materials. For example, a core of pure silicon oxide in a borosilicate coating will solidify while the coating is still liquid and will appear almost round. A similar fiber with a core of pure germanium oxide, a borosilicate coating and a Pyrex substrate tube has a flat, ribbon-shaped core. Presumably, the ellipticity of the core can be controlled by doping to change the melting point.

A fiber manufactured using the above-described method has maintained polarization over a length of 100 m with a quality of more than 100: 1 (ie when a bundle of polarized radiation was coupled into the fiber and the input end of the fiber was oriented such that the minimum amount of power from the output end was emitted in a plane at right angles to the main beam, that minimum amount was found to be less than 1% of the power of the main beam).

In the case of the fiber discussed above, the core is circular or only slightly elliptical, and the area of the greatest geometric deviation from the circular symmetry is the interface between coating and substrate, where the electromagnetic field is weak. Geometric factors are less important than stress-induced birefringence. The voltage birefringence is more than 5x10 5 in the embodiments described with reference to Figures 11-14.

The fiber is stretched because the substrate and core materials (essentially pure SiO2) have a different melting point than the coating doped to change the refractive index. When the molding cools after it has been compressed, the substrate first cools, creating the elliptical cross-section for the still liquid or soft coating. As the coating cools and hardens, the substrate prevents shrinkage and therefore it is required to occupy a larger volume than would be the case if the substrate were not present, resulting in tension of the fiber. Since the substrate is not circularly symmetrical, the voltage for different directions differs, which gives rise to birefringence.

The relative sizes of geometric and stress phenomena will depend on the shape of the fiber, the relative melting points and the thicknesses of the different layers and also on the method of drawing the molding into a fiber. The degree to which a particular fiber retains the polarization will also depend on the aspects of the fiber influencing the polarization, impurities, bubbles and irregularities in the fiber dimensions, inter alia, and the net result of these competing phenomena will have to be determined empirically in a particular case .

The above-described method uses an abrasive treatment to form a non-circular symmetrical substrate. The deviation from the circular symmetry need not be in the form of flat surfaces on the outside of the substrate. For example, the exterior surface 71 of the substrate may be elliptical and the interior 72 circular in cross section, as shown in Figure 13. The exterior surface 81 may be circular and the interior surface elliptical, such as

Claims (5)

193330 6 shown in Figure 14. In the latter case, the mechanical deformation of the interior produced by the surface tension on the outer surface is lost, but the mechanical stresses generated by the difference in thermal contraction will be retained. The described fiber included coatings with a melting point lower than the melting point of the substrate, so that the coat was under tensile stress. It is of course also possible to use combinations of coating and substrate, such that the substrate hardens last and compresses both the coating and the core. The fiber was a "W" fiber with two coating areas. The advantages of the stress birefringence also apply to a fiber with a single clad layer, either uniformly doped or with a radial gradient in the refractive index. Such a single coat layer fiber was prepared by a method which differed only there from the method described above that the mixture of 1% diborane in argon was passed at a rate of 20 cc / min. The location of the mechanical stress can be controlled by varying the composition of the coatings. The layer with the least melting point will harden last and the mechanical stress appears to be concentrated therein in the fiber shown. The mechanical stress can therefore be concentrated near the core or near the substrate depending on the melting points of the different layers and their coefficients of thermal expansion. The effect of the mechanical stress will also depend on the relative thicknesses at the core, coating and substrate, which is self-evident. Optical waveguide formed by a high temperature drawing operation from a preform composed of a core part, a cladding part enclosing the core part and a jacket part, characterized in that the construction of the preform is selected such that in the waveguide birefringence due to difference in mechanical stresses along two mutually perpendicular directions perpendicular to the axis of the waveguide is greater than 5 x 10 5 and that the thickness of the jacket of the waveguide in one of the mutually perpendicular directions is noticeable greater than in the other perpendicular direction. A method of manufacturing an optical waveguide according to claim 1, wherein a preform composed of a core part, a core part enclosing the core part and a jacket part is subjected to a high temperature drawing operation, characterized in that a preform in which the thickness of the cladding part in one of two mutually perpendicular directions is considerably greater than in the other perpendicular direction, the ratio of the radius c of the cladding part to the thickness a of the cladding part in the direction in which this thickness the greatest is less than 0.5 and the ratio of the smaller thickness b of the jacket part in the direction perpendicular to the direction of the greatest thickness relative to that greatest thickness a is equal to or 40 less than 0.1. The method of manufacturing an optical waveguide according to claim 1, wherein a preform composed of a core part, a core part enclosing the core part and a jacket part is subjected to a high temperature drawing operation, characterized in that a preform is used wherein a uniform thickness jacket portion is formed on the liner portion, said jacket portion having two diametrically opposed longitudinally extending slots along the preform. The method of manufacturing an optical waveguide according to claim 1, wherein a preform composed of a core portion, a core portion enclosing core portion and a sheath portion is subjected to a high temperature drawing operation, the preform being obtained by the coating portion and depositing the core portion in the form of layers on the inner surface of a tubular body forming the jacket portion and collapsing the hollow space of the tubular body with the deposited layers at a high temperature, characterized in that a tubular body is applied with such a predetermined shape that the thickness of the wall of the tubular body for a first direction perpendicular to the axis of the tubular body differs markedly from the thickness of the wall for a second direction perpendicular to the first direction and axis of the tubular body. Method for manufacturing an optical waveguide according to claim 4, characterized in that 7 193330 are used for the production of the preform such that the melting point of the cladding part is lower than the melting point of the tubular body forming the cladding part , inducing mechanical stresses when cooling the preform. Hereby 2 sheets drawing