RU2453511C1 - Method of forming optical waveguide immersed in glass - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: glass surface containing alkali metal ions, for example, Na, K, Li, in the region of formation of the waveguide is irradiated with electrons with energy 5-20 keV and radiation dose 0.5-10 mC/cm² with electron current density 0.5-10 mcA/cm². To increase the effective refraction index of the waveguide and increase its thickness, the glass is thermally treated at temperature 350-400°C for 1-2 hours after irradiation with electrons.

EFFECT: high accuracy and manufacturability of optical waveguides immersed in thin glass surface layers, with given shape and high effective refraction index and low optical losses, variation of the depth of the waveguide and thickness thereof.

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Description

The invention relates to the technology of optical materials and can be used in integrated optics for the manufacture of waveguides and waveguide structures, as well as for the manufacture of waveguide sensors and sensors.

The main component of integrated optical devices is an optical waveguide, which can be used both for transmitting optical signals and can be a part of integrated optical devices that control optical signals: optical switches and switches, waveguide filters, resonators, etc. An optical waveguide is an extended structure of an optically transparent material with a refractive index greater than the refractive index of the environment. For the manufacture of optical waveguides using methods of photolithography, vacuum deposition, diffusion, ion exchange, ion implantation and others. The last three methods are used to form embedded or submerged optical waveguides, i.e. waveguides located in the substrate volume of an integrated optical device.

A known method of forming immersed optical waveguides in dielectrics is that impurity ions (for example, metal ions) are introduced into the surface layer of a dielectric through a mask by diffusion [Taylor H.F., Martin W.E., Hall D.B. Fabrication of single-crystal semiconductor optical waveguides by solid-state diffusion. // Appl. Phys. Lett. 1972. V.21. I.3. P.95-98]. A change in the chemical composition of the surface layer leads to a local increase in the refractive index and the formation of an optical waveguide. The disadvantage of this method is the need to use photolithography for the manufacture of masks.

A known method of forming immersed optical waveguides in dielectrics, which consists in the fact that the surface layer of the dielectric is irradiated with accelerated impurity ions [Somekh S., Garmire E., Yariv A., Garvin H.L., Hunsperger R.G. Channel Optical Waveguides and Directional Couplers in GaAs-lmbedded and Ridged // Appl. Opt. 1974. V.13. I.2. P.327-330]. Impurity ions, penetrating into the surface layer of a dielectric, lead to a change in its chemical composition, to a local increase in the refractive index and the formation of an optical waveguide. The disadvantage of the implantation method is the need to use photolithography for the manufacture of masks.

A known method of forming immersed optical waveguides in dielectrics is that a surface layer of a dielectric, such as glass, is irradiated with focused laser pulses of femtosecond duration, the laser beam being moved along the direction of the waveguide being formed [G. Cheng, K. Mishchik, C. Mauclair, E .Audouard, R. Stian Ultrafast laser photoinscription of polarization sensitive devices in bulk silica glass // Opt. Express V.17. No 12. P.9515. 2009]. A modification of the glass structure in the irradiation zone leads to the appearance of local mechanical stresses that increase the refractive index and the formation of an optical waveguide. The disadvantage of this method is the pulse-periodic processing mode, leading to spatial heterogeneity of the generated waveguide.

A known method of forming immersed optical waveguides in glasses, which consists in the fact that the glasses are placed in a molten metal salt, for example silver nitrate, an ion exchange process is carried out, after which the glass is subjected to heat treatment [N.V. Nikonorov, G.T. Petrovsky. Glass for ion exchange in integrated optics: current status and trends for further development (review). // Phys. and chem. glass, 1999, T.25, No. 1, C.21-69. A. Tervonen, S. Honkanen, M. Leppihalme. Control of ion-exchange waveguide profiles with Ag thin-film sources // J. Appl. Phys. 62. N3. P.759. 1987]. During ion exchange, metal ions are introduced into the surface layer of the glass, which leads to an increase in the refractive index of this layer. The disadvantage of this method is the need to use additional photolithographic processes to create waveguides of a given configuration in the surface layer of glass.

A known method of forming layers of metal nanoparticles in glass, selected as a prototype, which consists in the fact that the glass containing silver or copper ions is irradiated with electrons, and then the glass is heat treated [patent application of the Russian Federation No. 2008143850, from 05.11.2008, solution on the grant of a patent dated February 17, 2010]. This method allows the formation of an immersed waveguide with metal nanoparticles in the surface layer of glass. The disadvantage of this method is the increase in the coefficient of optical absorption in the layer due to the formation of absorbing metal nanoparticles in it. Such a waveguide has high losses due to the presence of nanoparticles in it.

The invention solves the problem of improving the accuracy and manufacturability of manufacturing submerged optical waveguides of a given geometry with a high effective refractive index and low optical losses, as well as the possibility of varying the depth and thickness of the waveguide in the substrate.

The problem is solved as follows.

The surface layer of a glass containing alkali metal ions, for example, Na, K, Li, is irradiated with electrons with an energy of 5-20 keV and an irradiation dose of 0.5-10 mK / cm ² at an electron current density of 0.5-10 μA / cm ² in the waveguide formation region. After irradiation with electrons, the glass is subjected to heat treatment at a temperature of 350-400 ° C for 1-2 hours

The essence of the invention is illustrated as follows.

Upon electron irradiation of glass with alkali metal ions, the region of waveguide formation in the near-surface glass layer forms a negative space charge associated with the accumulation of thermalized electrons and high specific resistivity of the glass; the thickness of the space charge layer at an initial electron energy of less than 10 keV does not exceed 0.5 μm. The electric field generated by such a space charge layer can reach 100-200 kV / cm [M.Touzin, D. Goeriot, C. Guerret-Piécort, D.Juvé, D.Tréheux, H.-J.Fitting // J .Appl. Phys. 99. 114110. 2006]. An electric field of high tension leads to the appearance of field migration to the negative space charge region of positive alkali metal ions with high mobility in glasses [A.Tervonen, S. Honkanen, M. Leppihalme // J. Appl. Phys. 62. 759. 1987]. Field migration of positive ions occurs throughout the process of electron irradiation. As a result, part of the alkali metal ions from the bulk of the glass moves into the surface layer. In this case, a local region with a high concentration of alkali metal ions is formed near the glass surface, and a region with a low concentration of these ions is formed in the depth of the glass. This leads to the appearance in the surface layer of the glass of a region with a high refractive index, and in the depth of the glass, a region with a low refractive index relative to the refractive index of the original glass. Such a structure is an immersed optical waveguide with a gradient profile of the refractive index. The formation of a waveguide in the form of two layers — with increased and decreased refractive indices relative to the refractive index of the original glass, improves the channeling efficiency of waveguide modes.

Recording a waveguide using a scanning electron microscope that moves an electron beam over the surface of the substrate according to a given program allows you to form a waveguide of a given geometry. Changing the electron energy makes it possible to adjust the depth of the waveguide. When the electron energy varies from 5 to 20 keV, the depth of the waveguide center from the glass surface will vary from 0.5 to 6 μm. The use of a sharply focused electron beam makes it possible to obtain a spatial resolution of less than 10 nm [C. Pool, F. Owens. Nanotechnology. - M .: Technosphere, 2004, 328 p.], Which provides high precision manufacturing waveguide.

Subsequent heat treatment allows you to increase the effective refractive index of the waveguide by reducing local mechanical stresses in the glass, as well as increase the thickness of the waveguide due to thermal diffusion of alkali metal ions from the waveguide region. Since alkali metal ions, due to their high chemical activity, cannot form absorbing metal nanoparticles in glass, an increase in their concentration in the surface layer of the glass does not lead to an increase in absorption in the waveguide layer.

The invention is illustrated by the drawing, which shows the dependence of the effective refractive index of the formed waveguide layer on the angle of incidence of radiation on the input prism: 1 - before heat treatment, 2 - after heat treatment.

Further, the invention is disclosed by an example, which should not be construed by an expert as limiting the claims of the invention.

As a substrate for the waveguide, a plate made of sodium-boron-silicate glass is used, whose chemical composition is close to that of K8 optical glass. Plate thickness 2 mm. Glass refractive index n = 1.511. A layer of Al with a thickness of 100-200 nm is applied to the wafer by vacuum deposition to remove a charge from the glass surface when irradiated with electrons. Electron irradiation is performed using a scanning electron microscope by moving a focused electron beam along the waveguide being formed. Electron irradiation is performed in the following modes: electron energy - 10 keV, electron irradiation dose - 5 mK / cm ² , electron current density on the glass surface - 2.5 μA / cm ² , irradiation time - 1000 s. Electron irradiation is carried out at room temperature. After electron irradiation, the Al film is removed by chemical etching in a 10% aqueous KOH solution. Thus, an optical waveguide has already been formed in the surface layer of the glass. After that, in order to further increase the effective refractive index of the waveguide by reducing local mechanical stresses in the glass, and also to increase the thickness of the waveguide due to the thermal diffusion of alkali metal ions from the waveguide region, the glass is heat treated at a temperature of 350 ° C for 1 h.

The length of the generated waveguide is 15 mm. The effective refractive index was measured according to the method described in [BCGolubkov, N.N. Evtikhiev, V.F. Papulovsky. Integral optics in information technology. - M.: Energoatomizdat. 1985. 152 p.]. The input and output of linearly polarized radiation (TE polarization) with a wavelength of 0.63 μm into the waveguide was carried out by the prism method. The measurements showed that electron irradiation makes it possible to form a waveguide layer 0.5-1 μm thick near the glass surface with an effective refractive index n _eff = 1.537-1.575 for the TE ₀ waveguide mode. Thus, electron irradiation allows locally increasing the effective refractive index compared to the refractive index of the original glass by Δn = 0.064. Measurements showed that subsequent heat treatment of the glass leads to an increase in the effective refractive index of the waveguide for the TE ₀ mode to n _eff = 1.583 ... 1.595. Thus, the subsequent heat treatment allows one to locally increase the effective refractive index in comparison with the refractive index of the initial glass by Δn = 0.084. Measurement of the absorption spectra of the waveguide region using a Cary 500 spectrophotometer showed that in the spectral range of 0.4-1 μm, the absorption coefficient in the waveguide layer does not exceed the absorption coefficient of the original glass.

For the manufacture of optical waveguides by the proposed method can be used standard technological equipment:

For electron irradiation - scanning electron microscopes or installations for electronic lithography.

For heat treatment - programmable muffle furnaces.

The proposed technical solution allows to produce immersed optical waveguides in thin surface layers of glasses, to increase the accuracy and manufacturability of the manufacture of waveguide layers of a given geometry, with a high effective refractive index and low optical losses, as well as vary the depth of the waveguide in the substrate and its thickness, improves the channeling efficiency of the guided waveguide modes. The advantage of the method is its compatibility with electronic lithography, as well as the ability to record optical waveguides in standard optical silicate glasses produced by the industry.

Claims (2)

1. A method of manufacturing an immersed optical waveguide in glass, which consists in irradiating an electron beam of glass containing metal ions, characterized in that the surface layer of a glass containing alkali metal ions in the waveguide formation region is irradiated with electrons with an energy of 5-20 keV and a radiation dose of 0 , 5-10 mK / cm ² at an electron current density of 0.5-10 μA / cm. 2. The method according to claim 1, characterized in that after irradiation with electrons, the glass is subjected to heat treatment at a temperature of 350-400 ° C for 1-2 hours

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