EP1504294A2 - Integrated optics component comprising a cladding and method for making same - Google Patents

Abstract

The invention concerns an integrated optics component comprising in a substrate (7) at least an optical guide core (11) and at least a cladding (9), the core and the cladding being independent of each other in the substrate, at least one portion of said cladding enclosing at least one portion of said core to define at least one so-called interactive region (20) between the core and the cladding, the refractive index of the cladding being different from the refractive index of the substrate and lower than the refractive index of the core at least in the part proximate the core and at least in the interactive region, a light wave being introduced into said region through the guide and/or through the cladding. The invention is applicable in particular in the field of optical telecommunications for producing for example a spectral or spatial filter, or a Mach-Zehnder interferometer or a temperature sensor.

Description

 INTEGRATED OPTICAL COMPONENT COMPRISING AN OPTICAL SHEATH AND ITS MANUFACTURING METHOD

DESCRIPTION

Technical area

The present invention relates to an integrated optical component comprising an optical sheath and its production method.

The invention finds applications in all fields requiring a modification of the characteristics of the modes propagating in the core of an optical guide and / or the excitation of cladding modes and in particular in the field of optical telecommunications, to achieve in integrated optics, for example a spectral filter or a temperature sensor.

State of the art

Optical sheaths are essentially known in the field of optical fibers. Indeed, the optical sheaths conventionally surround the core of the fibers, they have a refractive index lower than that of the core which allows the propagation of a light wave in the core of these fibers.

By varying the value of the cladding refraction index, it is possible to modify the propagation characteristics of the propagation mode or modes in the core of an optical fiber and in particular to optimize its guiding properties and in particular to reduce the chromatic dispersion. . It is also known to use cladding modes, by making these optical claddings with fiber optic networks in order to couple one or more guided modes in the core of a fiber to the cladding mode (s) of the fiber or vice versa. . Reference may be made to this effect, for example, to US Pat. No. 5,430,817.

In all cases, the fiber core cannot allow correct propagation of a light wave without the optical sheath. The sheath and the heart are dependent and form the fiber.

FIGS. 1 and 2 schematically illustrate respectively in perspective and in section, an embodiment of an optical sheath used according to the prior art with a fiber optic network.

Thus, in FIG. 1, we see the core 1 of the fiber of refractive index n _c in which the light wave is guided, an optical sheath 2 of index ng which allows the guidance of this light wave by a change in index relative to the heart (n _c > ng) and a mechanical sheath 3 which protects the assembly. In Figure 1, to simplify the representation, the mechanical sheath has been voluntarily, partially removed. A network 6, represented in the section of FIG. 2 by an alternation of gray and white areas is produced in the core 1 of the fiber. This network is formed by the creation of zones (the shaded areas) in the heart with a refractive index greater than that of the rest of the heart (the white areas). This network makes it possible to couple a guided mode, symbolically represented by a set of concentric circles referenced 4, to one or more sheath modes 5 propagating in the optical sheath 2, in the same direction as the guided mode 4. The sheath modes are also symbolically represented by sets of concentric circles referenced 5.

The coupling between the different modes takes place for wavelengths determined λ _j by the following known relation:

with:

- n ₀ the effective index of guided mode 4,

- nj the effective index of the sheath mode number j - λ _j the resonance wavelength for coupling to mode j,

- During the network period.

In general, there is a small difference between the effective indices n ₀ and n _j (from some 10 ^"2 to some 10 ^{" 3} ), and the wavelength range concerned by the optical guidance is around 1.5 μm . As a result, relation (1) shows us that the periods of the networks are often of the order of a few tens of μm to a few thousand μm. Such a component is for example used as a filter element.

Indeed, the coupling results in a transfer of energy between the guided mode 4 and the cladding modes 5 for the wavelengths λj. The energy coupled in the cladding modes is then dispersed outside the cladding along the propagation of the modes in the cladding, so that the light wave recovered at the output of guide 1 has a power spectrum with energy losses for the wavelengths λj on so-called filtering spectral bands. In addition, the energy coupled in the cladding modes is not reflected by the network, which insulates the filter in terms of parasitic reflections. In integrated optics, the guiding of a light wave in the core of a guide is conventionally obtained by confining the core in one or more layers of a substrate, these layers having a refractive index lower than that of the core.

Furthermore, US Pat. No. 5,949,934 describes the use of an optical sheath on either side of a network formed in the heart of a guide in integrated optics, this assembly being arranged on a substrate. This sheath is produced by the superposition of layers between which the heart is sandwiched. In this patent, the heart is therefore dependent on the sheath since it cannot exist without the layers between which it is arranged. Thus, the sheath described in this patent makes it possible both to induce sheath modes and to provide support for the core of the guide. In addition, the sheath generally having the same refractive index as the substrate, the sheath does not differ optically from the substrate.

There is therefore currently no optical cladding associated with an optical guide core in integrated optics or even with a fiber core, which is independent of this core and vice versa. Statement of the invention

The object of the present invention is to propose an integrated optical component comprising at least one optical sheath which is independent of the guide core or cores with which it is associated. By independence of the core and of the sheath, it is meant that they can exist in a substrate independently of one another.

Another object of the invention is to provide an integrated optical component comprising at least one optical sheath associated with at least one optical guide core capable of modifying in particular at least one characteristic of the mode or modes propagating in the heart and / or to induce one or more propagation modes in this sheath.

The characteristics of the mode or modes propagating in the heart can be in particular the effective index, the size of the mode and / or the phase.

More specifically, the invention relates to an integrated optical component comprising in a substrate at least one optical guide core and at least one optical sheath, the heart and the sheath being independent of one another in the substrate , at least a portion of said sheath surrounding at least a portion of said core so as to define at least one so-called interaction zone between the heart and the sheath, the refractive index of the sheath is different from the refractive index of the substrate and lower than the refractive index of the heart at least in the part of the sheath close to the heart and at least in the interaction zone, a light wave being able to be introduced into said zone by the heart and / or by the sheath.

The substrate can of course be produced by a single material or by the superposition of several layers of materials. In the latter case, the refractive index of the cladding is different from the refractive index of the substrate at least in the layers adjacent to the cladding.

According to a preferred embodiment, the sheath and the core are produced from the substrate, by a modification of the refractive index of the substrate and not as in the prior art by transfer of layers.

According to the invention, the guide can be a planar guide, when the light confinement is in a plane containing the direction of light propagation or a microguide, when the light confinement is carried out in two directions transverse to the direction of light propagation. The core of the guide and the sheath are independent of each other, that is to say that they can exist in the substrate independently of each other.

Also, according to an advantageous embodiment of the invention, the sheath surrounds only a portion of the heart of the guide. Thus the sheath acts on the propagation of a light wave in the heart of the guide only in the interaction zone and the sheath can guide or convey light waves independently of the heart. The sheath being independent of the heart, the parameters of the sheath and the heart are easily adaptable to the desired applications. Thus, one can easily play on the dimensions, the value of the refractive index and the position of the sheath relative to the dimensions and the value of the refractive index of the core of the guide. It is thus possible to modify at least one characteristic of the mode or modes propagating in the core of the guide and / or of one or more modes of propagation in the sheath.

To induce sheath propagation modes, advantageously, the sheath has a higher refractive index than that of the substrate.

Furthermore, to induce these sheath modes, according to a first embodiment, the light wave is introduced into the sheath. And according to a second embodiment which can be combined with the first, the interaction zone comprises a network formed in the heart of the guide and / or in the sheath.

According to this second embodiment, when the light wave is introduced into the core of the guide then the guide mode is coupled to one or more of the sheath modes in the interaction zone and vice versa when the light wave is introduced into the sheath, the sheath mode or modes are coupled to the guided mode of the heart in the interaction zone. The network can be periodic or pseudoperiodic, it can also be composed of a succession of networks.

Many components in integrated optics can be produced by combining one or more guide cores with one or more optical sheaths of so as to create several interaction zones each zone which may or may not include a network.

Thus, a component can be produced comprising in a substrate a guide core comprising a first and a second end, an optical sheath and an interaction zone formed by a part of the sheath surrounding a part of the heart, said zone comprising a network. , a light wave being introduced into the heart by one of the ends and recovered at the exit of the heart by the other end.

Advantageously, the two ends of the heart are outside the interaction zone, which allows more flexibility in the introduction and / or recovery of the wave and better filtering when this component is used as a filter.

In fact, this component makes it possible in particular to produce an optical filter: the guided mode of the light wave introduced into the heart is coupled in the area of interaction by the network to one or more cladding modes for wavelengths λ _j defined in relation (1). The coupled part of the light wave in the sheath modes may or may not be recovered at the output of the sheath and the non-coupled part of the wave, that is to say the light wave filtered for the lengths of wave λ _j is recovered at the outlet of the heart.

Likewise, components according to the invention without a network can be produced.

In particular, the component of the invention can be an interferometer and comprises at least two guide cores having respectively a first and a second end, the first ends being connected to each other by a first Y junction and the second ends being connected to each other by a second Y junction, this component further comprising at least one sheath surrounding at least a portion of one of the cores .

Advantageously, the substrate is glass.

Of course, the substrate can also be made of other materials such as, for example, crystalline materials of the KTP or LiNb0 _{3 type} , or else LiTa0 ₃ .

Furthermore, the optical sheath and / or the core of the guide and / or the network can be produced by any type of technique making it possible to modify the refractive index of the substrate. Mention may in particular be made of ion exchange techniques, ion implantation and / or radiation, for example by laser exposure or laser photo-registration. More generally, the network can be produced by all the techniques making it possible to change the effective index of the substrate. To the aforementioned techniques, it is therefore possible to add in particular the techniques for producing networks by etching the substrate in the vicinity of the interaction zone. This etching can be performed above the interaction zone or in the sheath portion of the interaction zone and / or optionally in the core portion of the interaction zone. The pattern of the network can be obtained either by laser scanning in the case of the use of a radiation either by a mask. The latter can be the mask which makes it possible to obtain the heart and / or the sheath or a specific mask for the realization of the network.

The invention also relates to a method for producing a component in integrated optics comprising in a substrate at least one optical guide core and at least one optical sheath, the heart and the sheath being independent of each other in the substrate, at least a portion of said sheath surrounding at least a portion of at least one heart so as to define at least one so-called interaction zone between the heart and the sheath, the heart and the sheath being produced respectively by a modification of the refractive index of the substrate so that at least in the part of the sheath close to the core and at least in the interaction zone, the refractive index of the sheath is different from the index of refraction of the substrate and lower than the refractive index of the heart. The modification of the refractive index of the substrate is obtained in particular by radiation, for example by laser exposure or by laser photo-inscription and / or by introduction of ionic species.

According to a preferred embodiment, the method of the invention comprises the following steps: a) introduction of a first ionic species into the substrate so as to allow the obtaining, after step c) of the optical sheath, b) introduction of a second ionic species into the substrate so as to allow the core of the guide to be obtained after step c), c) burial of the ions introduced in steps a) and b) so as to obtain the sheath and the core of the guide.

The order of steps a) and b) can of course be reversed.

The introduction of the first and / or the second ionic species is advantageously carried out by ion exchange, or by ion implantation. The first and second ionic species can be the same or they can be different.

The introduction of the first ionic species and / or the introduction of the second ionic species can be carried out with the application of an electric field.

In the case of an ion exchange, the substrate must contain ionic species capable of being exchanged. According to a preferred embodiment, the substrate is glass and contains previously introduced Na ⁺ ions, the first and second ionic species are Ag ⁺ and / or K ⁺ ions.

According to a first embodiment, step a) comprises the production of a first mask comprising a pattern suitable for obtaining the sheath, the introduction of the first ionic species being carried out through this first mask and the step b) comprises the elimination of the first mask and the production of a second mask comprising a pattern suitable for obtaining the heart, the introduction of the second ionic species being produced through this second mask.

According to a second embodiment, step a) comprises the production of a mask comprising a pattern capable of obtaining the sheath and of the heart, the introduction of the first and second ionic species of steps a) and b) being made through this mask.

The masks used in the invention are for example made of aluminum, chromium, alumina or dielectric material.

According to a first embodiment of step c), the burial of the first ionic species is carried out at least partially before step b) and the burial of the second ionic species is carried out at least partially after the step b).

According to a second embodiment of step c), the burial of the first ionic species and the burial of the second ionic species are carried out simultaneously after step b).

According to a third embodiment of step c), the burial comprises a deposition of at least one layer of material with a refractive index advantageously lower than that of the sheath, on the surface of the substrate.

This mode can of course be combined with the two previous modes.

Advantageously, at least part of the burial is carried out with the application of an electric field. Generally before the burial in the field and / or the deposition of a layer, the method of the invention can also comprise a burial by rediffusion in an ion bath. This re-diffusion step can be carried out partly before step b) to re-diffuse the ions of the first ionic species and partly after step b) to re-diffuse the ions of the first and second ionic species. This re-diffusion step can also be carried out entirely after step b) to re-diffuse the ions of the first and second ionic species.

By way of example, this re-diffusion is obtained by immersing the substrate in a bath containing the same ionic species as that previously contained in the substrate.

Other characteristics and advantages of the invention will emerge more clearly from the description which follows, with reference to the figures of the appended drawings. This description is given purely by way of non-limiting illustration.

Brief description of the figures

Figures 1 and 2, already described, schematically show in perspective and in section an optical sheath associated with a network made in the heart of an optical fiber, Figure 3, schematically shows in perspective, an embodiment of the invention an optical sheath associated with a network produced in the heart of an optical guide, Figure 4 schematically shows in section, the example in Figure 3, Figure 5 gives schematically an example of a refractive index profile n obtained in an interaction zone according to the invention, Figure 6 schematically illustrates in section a first example of application of the component of the invention to form a filter, FIGS. 7a and 7b schematically illustrate respectively in perspective and in section a second example of application of the component of the invention to form an interferometer, FIGS. 8a to 8d illustrate schematically and in section an example of a method of producing a component according to the invention, FIGS. 9a to 9d schematically illustrate variants of the mask pattern making it possible to obtain a network in the heart, and - the Figure 10 shows in section an alternative embodiment of component according to the invention having a network in the sheath.

Detailed description of methods of implementing the invention

To simplify the description of all of these figures, there have been shown guide cores and sheaths with constant burial depth in the substrate, it being understood that, depending on the intended applications, the cores and sheaths can have varying burial depths. For the sake of simplification, the sheaths having a constant refractive index are described, but of course, it is entirely possible in the context of this invention to use sheaths having a variable index, as long as their indices in the vicinity of the heart is smaller than the refractive index of the heart.

Likewise, although the substrate may comprise one layer or several layers, it is represented in all of these figures as a substrate with a single layer.

FIGS. 3 and 4 represent respectively in perspective and in section an example of embodiment in optics integrated in a substrate 7 of an optical sheath 9 associated with a network 13 produced in the heart 11 of an optical guide. The section of Figure 4 is made in a plane parallel to the surface of the substrate and containing the heart 11. In this figure, the optical sheath 9 surrounds only the portion of the heart 11 which comprises the network 13. The area of the substrate which comprises both the sheath and the core of the guide is called the interaction zone.

We can clearly see in these figures, that the heart 11 exists independently of the sheath 9 since outside the interaction zone, the heart is no longer located in the sheath but only in the substrate 7 which allows optical isolation of the heart.

The sheath is thus created artificially, in the substrate, at least around a portion of the heart comprising the network and independently of the core and the substrate.

In general, an artificial sheath will be called this type of sheath produced according to the invention and an artificial sheath network, when the interaction zone comprises a network.

In this exemplary embodiment, the sheath is produced in the substrate so as to have a refractive index between that of the substrate and that of the core of the guide, which allows, thanks to the presence of the network 13, to have sheath modes referenced 15 in FIG. 4.

The network 13 produced in the core 11 in the interaction zone is a succession of periodic or pseudo-periodic patterns formed in this example by segmentation of the core 11.

Thus, when the guided mode, referenced 17, of the light wave which propagates in the core 11 arrives in the interaction zone defined by the part of the substrate which comprises both the sheath 9 and the core 11 provided here with the network 13, mode 17 will be coupled to one or more modes of sheath 15.

We could also have directly introduced the light wave into the sheath 15, the sheath mode or modes would then have been coupled to the mode guided by the heart by the network. To allow this introduction, the sheath is made so that one of its ends (referenced 19) is located for example on a side wall of the substrate. The independence of the sheath from the core of the guide makes it possible to adapt the parameters of the sheath (such as dimensions, index level and position) in relation to core parameters (such as dimensions, index level and position), to the intended applications. The coupling force between a guided mode and a given cladding mode is obtained by the product of the network length with the coupling coefficient

K. The latter is proportional to the overlap integral of the two coupled modes, weighted by the network profile.

If one notes ξ ₀ and ξ _j the transverse profiles of the modes respectively guided and sheath and Δn the profile of the network, the coupling coefficient K is given by a relation of the type:

where ds is an integrating element over the entire transverse surface of the substrate, that is to say in a plane perpendicular to the axis of propagation of the wave.

FIG. 5 gives an example of a refractive index profile n obtained in the interaction zone, in a direction x transverse to the direction of propagation of a light wave in the heart. On this profile we clearly see the dimension L _x of the sheath of index ng, in this direction as well as the dimension l _x of the core of index n _c , in this same direction. The index n _s of the substrate was taken as a reference. By varying the parameters of the cladding and of the core according to the intended applications, one naturally obtains other index profiles. Thus, at the level of the sheath, the larger its dimensions and its index level, the more sheath modes will be allowed to propagate and the more we will therefore have in the filtering application possible filter bands. This can be an advantage if you are looking for multiple filters or to have more room in choosing a filtering mode.

If one seeks to limit the number of cladding modes that can be coupled, it is conversely advantageous to reduce the opto-geometric dimensions of the cladding.

For other applications of the interferometer type, the choice of the level of index of the cladding is also important since it makes it possible to modify the difference in index that one has in equation (3) defined later.

At the level of the guide core, its dimensions and its index level condition the characteristics of the mode which propagates therein and make it possible for example to adapt it to a fiber mode, in the case of a guide core coupling / fiber core.

Furthermore, the greater the differences in index between the core, the cladding and the substrate, the more likely there is a chance of having couplings for periods of weak networks as shown in equation (1) (at a given resonance wavelength, the period is inversely related to the difference in index between the guided and cladding modes).

The fields of application of components comprising an optical sheath surrounding a network formed in the heart of a guide are the same as those of optical fibers comprising networks. Mention may in particular be made of applications such as suitable spectrum loss filters (linear filtering for example) or also sensor applications. Furthermore, the independence of the sheath from the heart allows many other applications, impossible to obtain with the concepts of the prior art.

The dimensions of the network can also be adapted to the intended applications. Thus, they can be networks of the long period type (for example from a few tens of μm to a few thousand μm) as well as networks with weaker periods (for example less than a few μm) such as the jaded or line networks. inclined. By way of example, FIG. 6 illustrates in section a first example of application of the component of the invention to form a filter.

Thus, FIG. 6 shows a component in integrated optics comprising in a substrate 7, a guide core 11, a sheath 9 surrounding the heart 11 in an interaction zone 20 comprising a network 13 produced in the heart. In this exemplary embodiment, the core of the guide enters the sheath by one end of the latter at the level of the interaction zone and emerges from the latter after the interaction zone, by curvature of the heart. The latter is thus separated from the sheath outside the interaction zone and the sheath remains present in the substrate without the core of the guide.

At the network 13 in the interaction zone, part of the signal guided in the heart is coupled to the sheath modes 15 or vice versa. Thus, when a light wave is introduced into the component through the end 11a of the heart 11, the guided mode of the heart is then coupled in the interaction zone by the network 13, to the sheath mode (s) for one or more filter bands defined spectrally by equation (1). On leaving the interaction zone, the part of the wave coupled to the sheath mode (s) propagates in the sheath while the rest of the initial wave is carried in the core 11 and can be recovered. by the end 11b of the heart.

We could also have planned operation in reverse. A light wave would then be introduced into the sheath at the end 17 of the sheath which does not include the heart. When passing through the interaction zone 20, the spectral part of the wave which corresponds to the filter band (s) of the network 13 is coupled into the core of the guide 11 and it can be extracted from the component by the end 11a of the heart.

As we have seen previously, the fact of producing an optical sheath which locally surrounds a portion of the guide core can find many other applications than those of coupling by a network.

Indeed, the use of an optical sheath according to the invention makes it possible to modify the characteristics of the mode propagating in the heart.

By way of example, FIGS. 7a and 7b respectively illustrate in perspective and in section in a plane perpendicular to the surface of the substrate and containing the interaction zone a second example. application of the component of the invention to form an ach-Zehnder type interferometer, this component having no network in the interaction zone.

This interferometer comprises in the substrate 7 a guide core 51 and a guide core 53 whose ends are respectively connected to junctions Y, referenced Y _τ and Y ₂ , thus forming two arms.

A sheath 52 surrounds a portion of the heart 51 and thus creates an interaction zone. A light wave introduced into

The interferometer, for example by the junction Yi, is therefore distributed in the two arms of the interferometer and then recombines at the output in the junction Y ₂ . The cumulative phase shift Δφ between the two arms determines the signal level obtained at the output of the component.

In the absence of the sheath 52, the interferometer is balanced and Δφ = 0.

In the presence of the sheath 52, the phase shift Δφ at the wavelength λ is expressed as follows:

Δφ = γ (n _effl -n _{e £ f2} ) xL (3)

n _eff i is the effective index of the guided mode in the core-substrate zone and n _eff2 is the effective index of the guided mode in the core-sheath zone and L is the length of the interaction zone which is in this example the length of the sheath. The difference ψ _{eff \} ~ ⁿ _eff i) can reach values of some 10 ^"2 .

Conventionally to achieve a non-zero phase shift, the skilled person plays on the length of the hearts. According to the invention, the use of a sheath allows achieving a non-zero phase shift between the two cores, these two cores possibly being of the same length, which simplifies the production of the component. In particular, a single mask of cores can cover a whole range of components which may have different phase shifts because only the parameters of the sheath are used to adjust these phase shifts.

Many applications of this interferometer are possible and in particular it allows the realization of spectral references (measurements of the pitch of the interfringes) or of attenuator at certain wavelengths (filter).

It also allows the creation of a temperature sensor. Indeed, in equation 3, the difference ψ _effx - n _eff2 ) between the effective indices of propagation of the guided mode with or without cladding depends in particular on the temperature, so that the phase shift at the output of the component is also a function of temperature. FIGS. 8a to 8d illustrate in section in a plane perpendicular to the surface of the substrate and containing the interaction zone, an example of a method for producing a component according to the invention, using ion exchange technology . Thus, in Figure 8a is shown a substrate 7 containing B ions.

A first mask 61 is produced for example by photolithography on one of the faces of the substrate; this mask has an opening determined as a function of the dimensions (width, length) of the sheath that it is desired to obtain. A first ion exchange is then carried out between ions A and ions B contained in the substrate, in a zone of the substrate located in the vicinity of the opening of the mask 61. This exchange is obtained for example by dipping the substrate provided with the mask in a bath containing ions A and possibly applying an electric field between the face of the substrate on which the mask is placed and the opposite face. The area of the substrate in which this ion exchange was carried out forms the sheath 63.

To bury this sheath, a step of re-diffusing the A ions is carried out with or without the assistance of an electric field applied as previously. Figure 8b shows the sheath after a partial burial step thereof. The mask 61 is generally removed before this step.

The production of the sheath according to the invention is therefore similar to the production of a guide core but with different dimensions. The next step shown in FIG. 8c consists in forming a new mask 65 on the substrate, for example by photolithography after optionally cleaning the face of the substrate on which it is produced. This mask comprises patterns capable of allowing the production of a guide core 67 and in particular when the core comprises a network, the patterns of the mask 65 can be adapted to the patterns of the network to be formed.

A second ion exchange is then carried out between the B ions of the substrate and C ions which may or may not be the same as the A ions. ion exchange can be carried out as previously by soaking the substrate in a bath containing C ions and possibly applying an electric field.

Finally, FIG. 8d illustrates the component obtained after burial of the core 67 obtained by re-diffusion of the C ions and final burial of the sheath, with or without the assistance of an electric field. The mask 65 is generally removed before this burial step. The conditions of the first and second ion exchanges are defined so as to obtain the desired differences in refractive indices between the substrate, the cladding and the core. The parameters for adjusting these differences are in particular the exchange time, the bath temperature, the ion concentration in the bath and the presence or absence of an electric field.

As an example of an embodiment, the substrate 7 is glass containing Na ⁺ ions, the mask 61 is made of aluminum and has an opening of approximately 30 μm in width (the length of the opening depends on the desired length of sheath for the intended application).

The first ion exchange is carried out with a bath comprising Ag ⁺ ions at approximately 20% concentration, at a temperature of approximately 330 ° C. and for an exchange time of approximately 5 minutes. A re-diffusion of the ions takes place first in the open air at a temperature of approximately 330 ° C. and for 30 s, then a partial burial of the sheath thus formed in the glass is carried out. This burial is carried out by a re-diffusion in a sodium bath at a temperature of around 260 ° C and for 3 minutes.

The mask 65 is also made of aluminum and has an opening pattern approximately 3 μm wide (the length of the pattern depends on the desired length of core for the intended application).

The second ion exchange is carried out with a bath comprising also Ag ⁺ ions at approximately 20% concentration, at a temperature of approximately 330 ° C. and during an exchange time of approximately 5 minutes, a redistribution of the ions at any point. 'first place in the open air at a temperature of about 330 ° C and for 30s. Then, a partial burial of the heart thus formed in the glass is carried out by re-diffusion into a sodium bath at a temperature of around 260 ° C. and for 3 min.

The final burial of the sheath and of the core is done under an electric field, the two opposite faces of the substrate are in contact with two baths (in this example sodium) capable of making it possible to apply a potential difference between these two baths.

Many variants of the previously described proσed can be realized. In particular, the steps of burying the sheath and the heart can be carried out as described previously in two successive steps but they can also be carried out in certain cases simultaneously, the heart having an ionic concentration higher than that of the sheath, it is buried faster than the sheath, which also allows centering of the heart in the sheath. The difference in concentration between the core and the sheath is generally obtained either by a re-diffusion in a bath of the ions forming the sheath or by a difference in concentration of the ions introduced in steps a) and b).

Furthermore, instead of using a mask to make the sheath and a mask to make the heart of the guide, when the heart and the sheath have the same length, a single mask can be used. For this, a mask is produced, for example by photolithography on the substrate, this mask having the pattern of the heart to be produced with or without a network depending on the intended application.

We carry out the first ion exchange to form the sheath, then a second ion exchange to form the heart and we bury the heart and the sheath.

By way of example in this embodiment for a glass substrate 7 containing Na ⁺ ions, the single mask is made of aluminum and has an opening pattern of approximately 3 μm in width (the length of the pattern depends on the desired length of sheath and core).

The first ion exchange is carried out with a bath comprising Ag ⁺ ions at low concentration approximately at 1%, at a temperature of approximately 330 ° C. and for an exchange time of approximately 20 minutes with the application of a field. electric. The redistribution of the ions in the glass takes place in the open air at a temperature of 330 ° C. for 30 s. The second ion exchange is carried out with a bath comprising also Ag ⁺ ions at about 20% of concentration, at a temperature of approximately 330 ° C. and for an exchange time of approximately 8 minutes. The redistribution of the ions in the glass takes place in the open air at a temperature of 330 ° C. for 30 s. Finally, the burial of the core and the sheath is carried out firstly by re-diffusion in a sodium bath at a temperature of around 260 ° C. and for 3 minutes, then by application of an electric field between the two opposite faces. of the substrate. As we have seen previously, in order to make the burial of the sheath and of the core, a variant of the method consists in depositing on the substrate 7, a layer of material 68, shown in dotted lines in FIG. 8d. This material, to allow optical guidance must advantageously have a refractive index lower than that of the sheath.

The production of the component according to the invention is not limited to the ion exchange technique. The component of the invention can of course be produced by all the techniques which make it possible to modify the refractive index of the substrate.

In the case of use in the interaction area of a network, its period, its size, its position relative to the core and to the cladding are parameters which can be adapted according to the applications.

The pattern of the network can be defined on the mask allowing the production of the sheath and / or on the mask allowing the production of the core or on the single mask allowing the production of both sheath and heart or even on a specific mask for the realization only of the network.

FIGS. 9a to 9d illustrate, by way of example, alternative embodiments of masks Mi, M ₂ , M ₃ , M ₄ making it possible to obtain a network. These figures are top views of the masks and represent only the part of the masks used to obtain the network. The white areas of the mask pattern correspond to the openings of the masks. These masks make it possible to obtain a periodic network of period Λ.

These masks can be, for example, specific masks for producing the network in the heart and / or in the sheath or a part of the masks enabling the heart and / or the sheath to be obtained, the network then being produced at the same time as the heart and / or the sheath.

Figure 4 previously described illustrates an example of a network formed in the heart of the guide. FIG. 10 illustrates an exemplary embodiment of a network 33 produced in an interaction zone both in the core 11 and in the sheath 9.

Thus, in FIG. 10, the network 33 is formed in the sheath 9 by an alternation of period Λ of zones 34 of variable width considered in the direction of propagation of a light wave. These zones have an effective index different from that of the rest of the cladding due to a modification of the refractive index of these zones. Since the core is also included in the sheath at least in the interaction zone, the network is also written in the heart, in other words the heart also has zones of refractive index different from that of the rest of the heart.

The networks can be formed by all the conventional techniques making it possible to locally modify the effective index of the substrate in the core and / or in the sheath.

It can therefore be carried out during ionic exchanges making it possible to produce the core and / or the sheath or during a specific ionic exchange. It can also be obtained by etching the substrate at the level of the interaction zone or by radiation. In particular, the network can be obtained by insolation of the heart and / or of the sheath with a C0 ₂ type laser. The laser, by producing localized heating, makes it possible to locally diffuse ions and thus to register the pattern of the network.

For example, the substrate can be scanned with a laser beam modulated, for example in amplitude, so as to introduce a modulation of the network at the desired step.

The reason for the network depends on the intended applications. In particular, the network can be of variable period (chirped network) or of variable efficiency (apodized network).

Claims

1. Component in integrated optics comprising in a substrate (7) at least one core (11) of optical guide and at least one optical sheath (9), the heart and the sheath being independent of each other in the substrate , at least a portion of said sheath surrounding at least a portion of at least one heart so as to define at least one so-called interaction zone (20) between the heart and the sheath, the index of refraction of the sheath being different from the refractive index of the substrate and lower than the refractive index of the heart at least in the part of the sheath close to the heart and at least in the interaction zone, a light wave being able to be introduced into the said zone by the heart and / or by the sheath.

2. Component according to claim 1 characterized in that the sheath has a refractive index higher than that of the substrate.

3. Component according to any one of claims 1 and 2 characterized in that the interaction zone comprises a network formed in the heart and / or in the sheath.

4. Component according to claim 3 characterized in that it comprises in the substrate (7) a core (11) of guide comprising first and second ends (11a, 11b), an optical sheath (9) and a zone of interaction (20) formed by part of the sheath surrounding a part of the heart, said zone comprising a network (13), a light wave being introduced into the heart by one of the ends and recovered at the outlet of the heart by the other end.

5. Component according to claim 4 characterized in that the two ends of the heart are outside the interaction zone.

6. Component according to any one of claims 1 to 5 characterized in that it comprises in the substrate (7) at least two guide cores (51, 53) having respectively first and second ends, the first ends being connected between them by a first Y junction (Yj and the second ends being connected together by a second Y junction (Y), this component further comprising at least one sheath (52) surrounding at least a portion of one of the hearts (51 ).

7. A method of producing a component in integrated optics according to any one of the preceding claims, characterized in that the core (11) and the sheath (9) are produced respectively by a modification of the refractive index of the substrate of so that at least in the part of the sheath close to the core and at least in the interaction zone, the refractive index of the sheath is different from the refractive index of the substrate and lower than the index of refraction of the heart.

8. Production method according to claim 7 characterized in that the modification of the refractive index of the substrate is obtained by radiation and / or by introduction of ionic species

9. Production method according to claim 8, characterized in that it comprises the following steps: a) introduction of a first ionic species into the substrate so as to allow the optical sheath to be obtained after step c), b) introduction of a second ionic species into the substrate so as to allow the core of the guide to be obtained after step c), - c) burial of the ions introduced in steps a) and b) so as to obtain the sheath and the heart of the guide.

10. Production method according to claim 9 characterized in that the introduction of the first and / or the second ionic species is carried out by ion exchange or by ion implantation.

11. Production method according to claim 10 characterized in that the substrate is glass and contains Na ⁺ ions, the first and second ionic species being Ag ⁺ and / or K ⁺ ions.

12. Production method according to claim 9 characterized in that step a) comprises the production of a first mask (61) comprising a pattern suitable for obtaining the sheath, the introduction of the first ionic species being carried out through this first mask and step b) comprises the elimination of the first mask and the production of a second mask (65) comprising a pattern suitable for obtaining the heart, the introduction of the second ionic species being carried out through this second mask.

13. Production method according to claim 9 characterized in that step a) includes the production of a mask comprising a pattern suitable for obtaining the sheath and the heart, the introduction of the first and second ionic species being made through this mask.

14. Production method according to any one of the preceding claims, characterized in that the interaction zone (20) comprising a network (13) this is obtained by modification of the effective index of the substrate in the sheath and / or the heart, in an appropriate pattern.

15. The production method according to claim 14 characterized in that the appropriate pattern of the network is obtained by introduction of ionic species through a mask allowing the obtaining of the heart and / or of the sheath or by a specific mask.

16. Production method according to claim 14 characterized in that the appropriate pattern of the network is obtained by local heating.

17. Production method according to claim 14 characterized in that the appropriate pattern of the network is obtained by etching the substrate in the vicinity of the interaction zone.

18. A production method according to claim 9 characterized in that the burial of the first ionic species is carried out at least partially before step b) and the burial of the first and second ionic species is carried out after the step b).

19. The production method according to claim 9 characterized in that the burial of the first ionic species and the burial of the second ionic species are carried out after step b).

20. Production method according to any one of claims 9 to 19 characterized in that at least part of the burial is carried out with the application of an electric field.

21. Production method according to any one of claims 9 to 20 characterized in that at least part of the burial is carried out by- a rediffusion in an ion bath.

22. Production method according to any one of claims 9 to 21 characterized in that all or part of the burial is carried out by depositing at least one layer on the surface of the substrate.

23. Production method according to any one of claims 9 to 22 characterized in that the introduction of the first ionic species and / or the introduction of the second ionic species are carried out with the application of an electric field.