INTERFEROMETRIC PHOTONIC SENSOR
Patent Information
- Authority / Receiving Office
- DE · DE
- Patent Type
- Patents
- Current Assignee / Owner
- COMMISSARIAT A LENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES
- Filing Date
- 2024-09-04
- Publication Date
- 2026-07-01
AI Technical Summary
Existing photonic sensors struggle to differentiate between changes in the refractive index of the surrounding medium due to bulk effects, such as water salinity or air pressure, and adsorption of molecules at the surface, leading to ambiguous sensor signals and errors.
The use of a hybrid interferometer with a reference arm as a waveguide and a measuring arm that propagates in free space in the ambient medium, allowing for the decoupling of volume and surface refractive index effects.
This approach enables accurate differentiation between bulk and surface refractive index changes, enhancing the sensor's precision and reducing signal ambiguity.
Description
[0001] The invention relates to the field of photonic sensors, and more particularly to sensors whose measurand is derived from a measurement of the change in refractive index of an ambient medium. The measurand can be, for example, the concentration of target molecules in a gas or liquid (gas sensor, biosensor, etc.), or directly the refractive index of a medium (refractometer). Advantageously, the invention is implemented using integrated photonic circuits, that is, circuits based on planar dielectric waveguides.
[0002] A planar waveguide is defined as a waveguide formed within a planar layer of an optoelectronic device. A planar waveguide may, in particular, have a rectangular cross-section.
[0003] It is known that the electromagnetic wave propagating in a dielectric waveguide exhibits an evanescent field extending over a distance called the penetration length Ld (or d1 / e) around the waveguide. Ld corresponds to the distance at which the electric field strength is divided by the constant e. Ld depends on the wavelength and refractive indices of the media through which the light passes, and is typically 75 to 150 nm for λ = (750 nm - 1500 nm) with SiN or Si waveguides in air. Generally speaking, we have L d = λ 2 π 1 n eff 2 − n a 2 where na is the optical index of the ambient medium and n eff the effective index of the guided mode.
[0004] Only changes in refractive index occurring in this region are likely to cause a change in the effective refractive index of the guided mode. Thus, even sub-nanometer layers of molecules adsorbed or captured on the surface of a waveguide can cause a measurable change in the effective refractive index. This is possible because the refractive index of the molecules is different (generally higher) than the refractive index of the covering medium, typically: nair = 1, nwater = 1.33, nbiomolecule = 1.45.
[0005] This effect is exploited, for example, to create integrated photonic biosensors, as illustrated in the [ Fig. 1A ] (plan view) and [ Fig. 1B ] (cross-sectional view AA). These figures represent, in a very schematic way, an integrated Mach-Zehnder interferometer (MZI) comprising a "reference" arm B1 and a "measuring" arm B2.
[0006] The measuring arm B2 has an upper surface in contact with an ambient medium MA, for example, a saline solution likely to contain biomolecules, while the reference arm B1 is separated from the ambient medium by a surface coating RS with a thickness much greater than Ld, typically at least a factor of 5, or even a factor of 10. Advantageously, the upper surface of the waveguide forming the measuring arm B2 has a functionalization layer CF adapted to selectively bind or adsorb a target biological (bacteria, virus, etc.) or chemical (protein, nucleic acid, etc.) species. If the target biological or chemical species is present in the ambient medium, the refractive index "seen" by a light wave propagating in the measuring arm changes. This induces a phase shift relative to the light wave propagating in the reference arm, and therefore a variation in the light intensity at the interferometer output.
[0007] In reality, the B1 and B2 arms of the interferometer are usually spirally wound to increase their length while maintaining the compactness of the device.
[0008] (Laplatine 2022) describes an olfactory sensor based on an array of 64 individual photonic sensors of the type shown in Figures [ Fig. 1A] et [Fig. 1B ].
[0009] One drawback of the architecture illustrated on the [ Fig. 1A] et [Fig. 1B The problem is that it cannot differentiate between a change in the refractive index of the surrounding medium in bulk—for example, caused by a change in water salinity or air pressure—and the adsorption of molecules at the surface. The sensor signal is therefore ambiguous and subject to error or uncertainty if both phenomena occur simultaneously, which is often the case in practice.
[0010] A known solution to this problem is to normalize the signal from the "sensor of interest" using a so-called reference sensor, whose measuring arm is not functionalized, or is even treated to minimize adsorption (using a so-called "blocking" or "anti-fouling" coating, for example, casein-based). This approach is used, for example, in the field of surface plasmon resonance sensors (see Karlsson 1995).
[0011] This solution requires very high specificity for chemical or biochemical recognition of the sensor of interest and very good blocking of the reference sensor. In practice, it works well when the concentrations of the target molecules (or those of any interfering substances) involved are sufficiently low and when the temporal variations in the optical index of the surrounding medium (for example, when replacing a first solution to be analyzed with a rinsing buffer solution, then with a second solution to be analyzed) remain limited. When these two conditions are not met, normalization is no longer effective and a spurious signal persists.
[0012] (Ignatyeva 2021) proposes differentiating the effects of bulk and surface refractive indices using a magnetophotonic crystal. This is a very complex solution to implement, requiring the use of "exotic" materials and an external magnetic field.
[0013] US 2007 / 0076212 A1 discloses an apparatus for examining atherosclerotic plaques by optical coherence tomography, based on a Michelson interferometer with one arm consisting of two optical fibers designed to be inserted into a blood vessel via a catheter. Light exits the end of the first optical fiber and is directed by a mirror toward the atherosclerosis. The light backscattered by the atherosclerosis is reflected by another mirror and coupled in a second optical fiber. This sensor does not allow for the measurement of a change in the refractive index of a medium.
[0014] JP 2018066664 A discloses an interferometric sensor comprising an integrated Mach-Zender interferometer, the two arms of which are formed by planar waveguides that intersect a fluidic channel. This sensor is intended solely for performing absorption spectroscopy measurements.
[0015] The invention aims to overcome, at least in part, the aforementioned drawbacks of the prior art. More specifically, it aims to provide a photonic sensor that allows for the simple and efficient decoupling of the effects of changes in volume and surface refractive index.
[0016] According to the invention, this goal is achieved through the use of an interferometer which can be described as "hybrid" because the reference arm is a waveguide, while the measuring arm includes a portion propagating in free space in the ambient medium.
[0017] An object of the invention is therefore a photonic sensor according to claim 1.
[0018] Specific embodiments of the invention are the subject of dependent claims. Other features, details, and advantages of the invention will become apparent from the description given with reference to the accompanying drawings, which are provided by way of example and represent, respectively: [ Fig.1A] et [Fig. 1B ], already described, a plan view and sectional view AA, respectively, of a photonic sensor according to the prior art; [ Fig. 2 ], a plan view of a sensor according to a first embodiment of the invention; [ Fig. 3 ], [ Fig. 4 ], [ Fig. 5 ] And [ Fig. 6 ] cross-sectional views of sensors according to four variants of said first embodiment of the invention; [ Fig. 7 ], a cross-sectional view of a sensor according to a second embodiment of the invention; [ Fig. 8], [Fig. 9 ], [ Fig. 10 ] plan views of sensors of various variants of a third embodiment of the invention; and [ Fig. 11 ], [ Fig. 12] et [Fig. 13 ], detailed cross-sectional views of various variants of said third embodiment of the invention.
[0019] A photonic sensor CP1 according to a first embodiment of the invention is described below with reference to the [ Fig. 2 ] - plan view - and at the [ Fig. 4], [Fig. 5 ] And [ Fig. 6 ] - cross-sectional views of different variants.
[0020] We define an orthogonal coordinate system X, Y, Z in which the plane (X, Y) is the plane along which a principal surface of a substrate extends.
[0021] The CP1 photonic sensor includes an interferometer I1 having a first arm BR1 and a second arm BR2. The first arm BR1 comprises a first optical waveguide G1 and a second optical waveguide G1', separated from the first optical waveguide G1 by a gap. The second arm BR2 comprises an optical waveguide G2.
[0022] The first arm BR1 includes at least one first coupling device DC1 between a guided propagation mode in the first optical waveguide G1 and a free propagation mode in an ambient medium MA.
[0023] The first arm BR1 also includes a second coupling device DC2, separate from said first coupling device DC1, between said free propagation mode in the ambient medium MA and the guided propagation mode in the second optical waveguide G1'.
[0024] Said first coupling device DC1 is configured to extract a light wave from the first waveguide G1' and said second coupling device DC2 to reinject it into the second waveguide G1'.
[0025] The first arm BR1 also includes an optical system SO1.
[0026] The optical system SO1 is configured to direct said free propagation mode towards said second coupling device DC2.
[0027] The first and second coupling devices DC1, DC2 and the optical system SO1 of the first arm BR1 allow a light wave passing through said first arm BR1 to carry out a part trMA of its path in said ambient medium MA, corresponding to the interval separating the first waveguide G1 from the second waveguide G1'.
[0028] Optical waveguides G1 and / or G1' can be planar waveguides.
[0029] The first coupling device DC1 can be a diffraction grating, in particular integrated into a planar layer CO1 comprising the first optical waveguide G1. The second coupling device DC2 can be a diffraction grating, in particular integrated into a planar layer CO1 comprising the second optical waveguide G1'.
[0030] The first arm BR1 can be a measuring arm and the second arm BR2 can be a reference arm.
[0031] According to the first embodiment, the interferometer I is, for example, of the Mach-Zehnder type.
[0032] A CP11 photonic sensor according to a first variant of the first embodiment is described below in relation to the [ Fig. 3 ].
[0033] The optical waveguide G1 of the first arm BR1 of the photonic sensor CP1 is arranged for example on a substrate S1.
[0034] The optical waveguide G1 can be located in a planar layer CO1 covering one face of the substrate S1. The surface of the interferometer intended to be in contact with the ambient medium MA can include at least a portion of the FL face of the planar layer CO1 opposite the FS face of the planar layer CO1 in contact with the substrate S1.
[0035] The planar layer CO1 can consist of a stack of a first layer CO11 and a second layer CO21. The first layer CO11 is, for example, made of silicon. The second layer CO21 can include at least one dielectric material, for example, silicon oxide. The optical waveguide G1 can be located within the second layer CO21.
[0036] The SO1 optical system comprises a first optical reflector R1 and a second optical reflector R2.
[0037] The first optical reflector R1 is configured to direct the light wave extracted from the first waveguide G1 by the first coupling device DC1 towards the second optical reflector R2. The second optical reflector R2 is configured to direct at least part of the light wave towards the second coupling device DC2, reinjecting it into the second waveguide G1'.
[0038] According to the first variant of the first embodiment, the first optical reflector R1 comprises a prism PR1. The second optical reflector R2 comprises a prism PR2.
[0039] The first optical reflector R1 comprises a first face F11, a second face F12, and a third face F13. The second optical reflector R2 comprises a first face F21, a second face F22, and a third face F23.
[0040] The first face F11 of the first optical reflector R1 is located opposite the first coupling device DC1. The second face F12 of the first optical reflector R1 is inclined with respect to the first face F11, in particular at an angle equal to or substantially equal to 45°.
[0041] The first face F11 of the first optical reflector R1 can be in contact with the face FL of the planar layer CO1.
[0042] The first face F21 of the second optical reflector R2 is located opposite the second coupling device DC2.
[0043] The second face F12 of the first optical reflector R1 is configured to reflect the light wave extracted from the first waveguide G1, notably towards the second face F22 of the second optical reflector R2.
[0044] The second face F22 of the second optical reflector R2 is configured to reflect the light wave, notably towards the second coupling device DC2.
[0045] The first face F21 of the second optical reflector R2 can be in contact with the face FL of the planar layer CO.
[0046] The third face F13 of the first optical reflector R1 is arranged opposite the third face F23 of the second optical reflector R2.
[0047] The first and second coupling devices DC1, DC2 can be arranged in the photonic circuit such that the third face F13 of the first optical reflector R1 is located at a distance from the third face F23 of the second optical reflector R2. The distance F13 - F12 is typically at least 1 mm and can reach 1 cm, or even several centimeters.
[0048] A light wave passing through the first arm BR1 travels part of its path in the ambient medium MA, notably between the third face F13 of the first optical reflector R1 and the third face F23 of the second optical reflector R2.
[0049] The third face F13 of the first optical reflector R1 may be perpendicular or substantially perpendicular (within manufacturing tolerances) to the face FL of the planar CO layer. The third face F23 of the second optical reflector R2 may be perpendicular or substantially perpendicular (within manufacturing tolerances) to the face FL of the planar CO layer.
[0050] According to this first variant of the first embodiment, the first coupling device DC1 may include a diffraction grating RD11 configured to diffract the light wave propagating in the first waveguide G1 in a direction perpendicular to its free face FL. Such a grating is known, in particular, from (Zhang 2019). Similarly, the second coupling device DC2 may include a diffraction grating RD12 configured to diffract the light wave propagating in free space in a direction perpendicular to the free face FL of the second waveguide G1' to couple it to a guided mode of the latter. For the diffracted light wave to propagate in the MA medium in a direction substantially parallel to the FL face, the second face F22 of the second optical reflector R2 is inclined relative to the first face F21, in particular at an angle of 45° or substantially 45°.
[0051] The RD11 and RD12 diffraction gratings can be manufactured by known laser engraving or direct writing techniques.
[0052] A CP12 photonic sensor according to a second variant of the first embodiment is described below in relation to the [ Fig. 4 ]. Elements common to those of the CP11 photonic sensor are designated by the same references and are not described again below.
[0053] The first coupling device DC1 includes a diffraction grating RD21. The second coupling device DC2 includes a diffraction grating RD22. Unlike the case of the [ Fig. 3 ], the RD21 and RD22 diffraction gratings are configured to diffract the light wave propagating in the waveguide in a direction forming an angle of approximately 8° with respect to the free face FL of the latter.
[0054] The first optical reflector R1 includes a prism PR12. The second optical reflector R2 includes a prism PR22.
[0055] The PR12 prism comprises a first face F112, a second face F122, and a third face F132. The PR22 prism comprises a first face F212, a second face F222, and a third face F232.
[0056] The first face F112 of the prism PR12 is located opposite the first coupling device DC1. The second face F122 of the prism PR12 is inclined relative to the first face F112.
[0057] The first face F212 of the prism PR22 is located opposite the second coupling device DC2. The second face F222 of the prism PR22 is inclined relative to the first face F212.
[0058] The second face F122 of the PR12 prism is configured to reflect the light wave extracted from the first waveguide G1, notably towards the second face F222 of the PR22 prism.
[0059] The second face F222 of the PR22 prism is configured to reflect the light wave, notably towards the second coupling device DC2.
[0060] The third face F132 of the PR12 prism is arranged opposite the third face F232 of the PR22 prism.
[0061] For the light wave reflected on the second face F122 of the prism PR12 to propagate parallel or substantially parallel to the (X, Y) plane, the reflecting faces F122 and F222 are inclined at an angle of 41° or substantially equal to 41° with respect to the first faces F112, F212, respectively.
[0062] In the photonic sensors of the [ Fig. 3 ] And [ Fig. 4 ], the angular dispersion of the beams diffracted by the RD11 and RD21 diffraction gratings induces losses, as can be clearly seen on the [ Fig. 3 To minimize these losses, it is possible to use long diffraction gratings to reduce angular dispersion. It is also possible to use an optical ray collimation system, as illustrated in the [ Fig. 5 ] And [ Fig. 6 ].
[0063] A CP13 photonic sensor according to a third variant of the first embodiment is described below in relation to the [ Fig. 5 ]. Elements common to those of the CP1 photonic sensor and / or the CP2 photonic sensor are designated by the same references and are not described again below.
[0064] The first optical reflector R1 comprises a prism PR13 having a first face F113, a second face F123, and a third face F133. The second optical reflector R2 comprises a prism PR23 having a first face F213, a second face F223, and a third face F233.
[0065] The first face F113 of the prism PR13 is located opposite the first coupling device DC1. The second face F123 of the prism PR13 is inclined relative to the first face F113.
[0066] The first face F213 of the PR13 prism is located opposite the second coupling device DC2. The second face F223 of the PR23 prism is inclined relative to the first face F213.
[0067] As explained above, the inclination of the faces F123 and F223 is chosen according to the diffraction angles of the diffraction gratings so that the light wave reflected on the second face F123 of the prism PR13 propagates parallel or substantially parallel to the (X, Y) plane.
[0068] The second face F123 of the PR13 prism is configured to reflect the light wave extracted from the first waveguide G1, notably towards the second face F223 of the lens L2.
[0069] The second face F223 of the PR23 prism is configured to reflect the light wave, notably towards the second coupling device DC2.
[0070] The third face F133 of the PR13 1 prism is arranged opposite the third face F233 of the PR23 prism.
[0071] The third face F133 of the PR13 prism is convex, so as to form a converging lens L1 adapted to collimate the light beam from the coupling device DC1 and reflected by the second face F123.
[0072] The third face F233 of the PR23 prism is convex, forming a converging lens L2. Lens L2 is designed to focus the light wave towards the second coupling device DC2.
[0073] A CP14 photonic sensor according to a fourth variant of the first embodiment is described below in relation to the [ Fig. 6 ]. Elements common with those of the CP1 photonic sensor and / or the CP2 photonic sensor and / or the CP3 photonic sensor are designated by the same references and are not described again below.
[0074] The first optical reflector R1 includes a PR14 prism. The second optical reflector R2 includes a PR24 prism.
[0075] The PR14 prism comprises a first face F114, a second face F124, and a third face F134. The PR24 prism comprises a first face F214, a second face F224, and a third face F234.
[0076] The first face F114 of the prism PR14 is located opposite the first coupling device DC1. The second face F124 of the prism PR14 is inclined relative to the first face F114.
[0077] The first face F214 of the PR24 prism is located opposite the second coupling device DC2. The second face F224 of the PR24 prism is inclined relative to the first face F214.
[0078] The second face F124 of the PR14 prism is configured to reflect the light wave extracted from the first waveguide G1, notably towards the second face F224 of the PR24 prism.
[0079] The second face F224 of the PR24 prism is configured to reflect the light wave, notably towards the second coupling device DC2.
[0080] The third face F134 of the PR14 prism is arranged opposite the third face F234 of the PR24 prism.
[0081] The second face F124 of the PR14 prism can be concave, on the side oriented towards the first coupling device DC1, in particular to focus or collimate the light wave by reflecting it.
[0082] The second face F224 of the PR24 prism can be concave, on the side oriented towards the second coupling device DC2, in particular to collimate the light wave by reflecting it.
[0083] As explained above, the inclination of the faces F124 and F224 is chosen according to the diffraction angles of the diffraction gratings so that the light wave reflected on the second face F123 of the reflector R1 propagates parallel or substantially parallel to the (X, Y) plane.
[0084] The third variant of the first embodiment can be combined with the first, second or fourth variant of the first embodiment.
[0085] In the four variants described above, the light wave extracted from the first waveguide G1 can be reflected off the second face F12, F122, F123, F124 of the first optical reflector R1 by total internal reflection. The light wave can then also be reflected off the second face F22, F222, F223, F224 of the second optical reflector R2 by total internal reflection.
[0086] Optionally, in the four variants described above, the second face F12, F122, F123, F124 of the first optical reflector R1 may be covered with a reflective layer or reflective coating or a thin reflective film CR1, on the side of the second face F12, F122, F123, F124 oriented towards the first coupling device DC1. The reflective layer CR1 may include at least one metallic material, for example gold.
[0087] Optionally, in the four variants described above, the second face F22, F222, F223, F224 of the second optical reflector R2 may be covered with a reflective layer or reflective coating or a thin reflective film CR2, on the side of the second face F22, F222, F223, F224 oriented towards the second coupling device DC2. The reflective layer CR2 may include at least one metallic material, for example gold.
[0088] The first optical reflector R1 and the second optical reflector R2 can be manufactured by three-dimensional printing, also known as 3D printing, notably exploiting two-photon polymerization as described by (Dietrich 2018) or direct laser writing as described by (Malinauskas 2012).
[0089] A C2 photonic sensor according to a second embodiment of the invention is described below with reference to the [ Fig. 7 This second embodiment differs from the first embodiment essentially by the structure of the optical system allowing the free propagation of the light wave in the surrounding medium.
[0090] The C2 photonic sensor includes an I2 interferometer, for example of the Mach-Zehnder type, having a first arm BR12 and a second arm. The first arm BR12 includes an optical waveguide G12.
[0091] The first arm BR12 includes a first coupling device DC12 between a guided propagation mode in the waveguide and a free propagation mode in the ambient medium MA. The first arm BR12 includes a second coupling device DC22 between said free propagation mode in the ambient medium and a guided propagation mode in the waveguide G12. The second coupling device DC22 is notably distinct from said first coupling device DC12. The first and second coupling devices DC12 and DC22 may be diffraction gratings.
[0092] The first arm BR12 includes an optical system SO2 configured to direct said free propagation mode to said second coupling device DC2.
[0093] The first arm BR12 can be a measuring arm and the second arm can be a reference arm.
[0094] The second arm may have a surface that can be brought into contact with an ambient MA environment and has a functionalization layer allowing the specific binding of chemical or biological species.
[0095] The G12 optical waveguide can be a planar waveguide.
[0096] The first coupling device, DC12, is configured to extract a light wave from the waveguide G12. The second coupling device, DC22, is configured to reinject the light wave into the waveguide G12.
[0097] The SO2 optical system of the first BR12 arm includes a first optical reflector R12 and a second optical reflector R22.
[0098] The G12 optical waveguide is, for example, arranged on an S12 substrate.
[0099] The optical waveguide G12 can be located in a planar CO2 layer covering one face of the substrate S12. The surface of the interferometer I intended to be in contact with an ambient medium MA can include at least a portion of the FL2 face of the planar CO2 layer opposite the FS2 face of the planar CO layer in contact with the substrate S12.
[0100] The planar CO2 layer can consist of a stack of a first CO12 layer and a second CO22 layer. The first CO12 layer is, for example, made of silicon. The second CO22 layer can include at least one dielectric material, for example, silicon oxide. The optical waveguide G12 can be located within the second CO22 layer.
[0101] The first optical reflector R12 is configured to direct the light wave extracted from the optical waveguide G12 by the first coupling device DC12 to the second optical reflector R22, which is itself configured to direct said light wave to the second coupling device DC22, reinjecting it into the waveguide G12.
[0102] The first optical reflector R12 includes an inclined face FI1. The second optical reflector R22 includes an inclined face FI2.
[0103] The inclined face FI1 of the first optical reflector R12 is configured to reflect the light wave extracted from the waveguide G12, notably towards the inclined face FI2 of the second optical reflector R22.
[0104] The inclined face FI2 of the second optical reflector R22 is configured to reflect the light wave, notably towards the second coupling device DC22.
[0105] The inclined face FI1 and the inclined face FI2 of the first and second optical reflectors R12, R22, respectively, are formed in particular from the first and second side walls PL1, PL2 of a trench T obtained by anisotropic wet etching of a single-crystal substrate or a single-crystal layer S2, for example in silicon.
[0106] The inclined face FI1 of the first optical reflector R12 can be inclined relative to the face FL2 of the planar CO2 layer, in particular by an angle of 54.7° or approximately 54.7°, which corresponds to the orientation of a {1 1 1} crystal plane of a silicon substrate. The inclined face FI2 of the second optical reflector R22 can be inclined relative to the face FL2 of the planar CO2 layer, in particular by an angle of 180° - 54.7° = 125.3° or approximately this value, which corresponds to the orientation of a {1 1 1} crystal plane of a silicon substrate. The angles are measured here in the counterclockwise direction.
[0107] The first and second optical reflectors R12, R22, together with the waveguide G12, form or delimit a fluidic conduit CF for the ambient medium MA. A light wave OL passing through the first arm BR12 travels part of its path within the ambient medium MA, inside the fluidic conduit CF.
[0108] The CF fluidic conduit is, for example, a micro-fluidic conduit. By micro-conduit, we mean, in particular, a conduit with dimensions of millimeters or sub-millimeters.
[0109] Optionally, according to the second embodiment, the inclined face FI1 of the first optical reflector R12 and the inclined face FI2 of the second optical reflector R22 may be coated with a reflective layer, reflective coating, or reflective thin film on the side facing the first coupling device DC12 and the side facing the second coupling device DC12, respectively. The reflective layer may comprise at least one metallic material, for example, gold. The reflective layer may be of the Bragg mirror type, formed in particular by a plurality of flat surfaces of silicon dioxide (SiO2) and by a plurality of flat surfaces of silicon nitride (SiN).
[0110] As illustrated in the upper part of the [ Fig. 7 The T-shaped trench can be created by wet etching. This involves covering a SU surface extending along a crystalline plane {100}, {010}, or {001} of a single-crystal silicon substrate with an HM mask. A chemical etch is then performed through an opening in the mask.
[0111] The trench T comprises a first side wall PL1 and a second side wall PL2. In the case of a single-crystal silicon substrate S2, the anisotropic wet etching can be carried out so that the first and second side walls PL1, PL2 extend along a crystalline plane {111}.
[0112] The trench T may further include a bottom F which may further delimit the fluidic conduit CF after assembly of at least a portion of the monocrystalline layer or the monocrystalline substrate S2 on the CO2 layer.
[0113] The fluidic conduit CF may have a trapezoidal cross-section in a plane (X, Z). Optionally, the bottom F may be covered with a reflective layer, a reflective coating, or a thin reflective film, in particular the same layer as that covering the first and second inclined faces FI1, FI2.
[0114] One advantage of a C2 photonic sensor of the type described in relation to the [ Fig. 7 ] is related to the fact that it is quick to manufacture and has a low cost.
[0115] One advantage of such a C2 photonic sensor lies in the fact that a plurality, in particular thousands, of first and second optical reflectors R12, R22 and fluidic conduits CF can be produced simultaneously on the same substrate S12. In this way, a plurality, in particular thousands, of first and second optical reflectors R12, R22 can be assembled simultaneously with a CO2 layer comprising a waveguide G12 and covering the same substrate S12, thanks, for example, to a single step of bonding the substrate or the S2 layer to the substrate S12 with interposition of the optical waveguide G12.
[0116] One advantage of such a C2 photonic sensor is that the tilt of the first and second optical reflectors R12, R22 relative to the optical waveguide G12 can be identical or nearly identical for a plurality of first and second optical reflectors R12, R22 arranged on the same substrate S12 or on different S12 substrates, thanks to the fact that this tilt depends on the crystalline structure of the substrate S2. The diffraction gratings of the DC12 and DC22 coupling devices must be adapted to these tilts, but this does not pose any particular difficulty.
[0117] The assembly of the first and second optical reflectors R12 and R22 onto the substrate S12, with the optical waveguide G12 interposed, can be achieved by bonding, preferably at room temperature—for example, bonding with a polymer adhesive (UV adhesive), applied, for instance, by screen printing—to ensure compatibility with biomolecule functionalization. In other embodiments, anodic, molecular, or eutectic bonding can be used. This results in good mechanical and thermal stability for such a C2 photonic sensor.
[0118] A C31 photonic sensor according to a first variant of a third embodiment is described below with reference to the [ Fig. 8 ].
[0119] The C31 photonic sensor includes an I3 interferometer with a first arm BR13 and a second arm BR23. The first arm BR13 includes an optical waveguide G13. The second arm BR23 includes an optical waveguide G23.
[0120] The first arm BR13 includes a coupling device DC3 between a guided propagation mode in the optical waveguide G13 and a free propagation mode in the ambient medium MA. The first arm BR13 includes an optical system SO3 configured to direct said free propagation mode towards said coupling device DC3 between said free propagation mode in the ambient medium and a guided propagation mode in the optical waveguide G13. A light wave OL passing through said first arm BR13 travels part of its path in said ambient medium MA.
[0121] The first arm BR13 can be a measuring arm and the second arm BR23 can be a reference arm.
[0122] The DC3 coupling device can be a diffraction grating.
[0123] The second arm BR23 may have a surface that can be brought into contact with said ambient medium MA and having a functionalization layer allowing the specific fixation of chemical or biological species.
[0124] The G13 optical waveguide can be a planar waveguide. The G23 optical waveguide can be a planar waveguide.
[0125] According to the third embodiment, the interferometer I3 can be a Michelson-type interferometer. The first arm BR13 comprises a unique coupling device DC3 configured to extract a light wave from the optical waveguide G13 and to reinject it into the optical waveguide G13 after reflection by an optical reflector R3 of an optical system SO3, spaced from said coupling device DC3. A light wave OL passing through said first arm BR13 thus travels part of its path in said ambient medium MA.
[0126] The DC3 coupling device is intended to achieve coupling between a guided propagation mode in the optical waveguide G13 and a free propagation mode in an ambient medium MA.
[0127] The SO3 optical system is configured to direct said free propagation mode towards said coupling device DC3.
[0128] The second arm BR23 of the I3 interferometer may include an M mirror.
[0129] According to this first variant of the third embodiment, the mirror M is formed by a loop of the optical waveguide G23, notably located in a planar layer CO3.
[0130] The I3 interferometer may include an SE3 splitter, for example made using a multimode interferometer, to separate a light wave OL from an input port into a first component directed to the first arm BR13 and a second component directed to the second arm BR23, and to recombine the light waves from the first and second arms and direct them to an output port.
[0131] A C32 photonic sensor according to a second variant of the third embodiment is described below with reference to the [ Fig. 9 ]. Elements common with those of the first variant of the third embodiment are designated by the same references.
[0132] According to this second variant of the third embodiment, the mirror M comprises a Bragg mirror MB, notably formed by an alternation of materials with different refractive indices, separated by flat surfaces.
[0133] A C33 photonic sensor according to a third variant of the third embodiment is described below with reference to the [ Fig. 10 ]. Elements common with those of the first and second variants of the third embodiment are designated by the same references.
[0134] According to this third variant of the third embodiment, the interferometer I3 comprises a circulator CI3 instead of the separator SE3 implemented using a multimode interferometer. The circulator CI3 exhibits lower losses than a multimode interferometer, but its implementation—particularly its integrated design—is more complex.
[0135] According to this third variant of the third embodiment, the mirror M can be formed by a loop of the optical waveguide G23, in particular located in a planar layer CO3.
[0136] A first variant of the first arm BR13 of an I3 interferometer of a C311 photonic sensor according to the third embodiment of the invention is described below with reference to the [ Fig. 11 ].
[0137] The optical waveguide G13 of the first arm BR13 of the C311 photonic sensor is arranged, for example, on an S3 substrate.
[0138] The G13 optical waveguide can be formed in a planar CO3 layer.
[0139] The planar CO3 layer can consist of a stack of a first CO13 layer and a second CO23 layer. The first CO13 layer is, for example, made of silicon. The second CO23 layer can include at least one dielectric material, for example, silicon oxide. The optical waveguide G13 can be located within the second CO23 layer.
[0140] The R3 optical reflector may include a mirror, for example a planar one.
[0141] The optical reflector R3 comprises a reflective face F311 opposite the optical waveguide G13. The optical reflector R3 and the optical waveguide G13 are separated, for example, by a distance d. This distance d is, for example, on the order of 150 micrometers. The optical reflector R3 can be formed in a planar layer that, together with the optical waveguide G13, defines a microchannel for the ambient medium MA.
[0142] The DC3 coupling device may include an RD311 diffraction grating.
[0143] According to this first variant, the RD311 diffraction grating is notably configured to diffract the light wave propagating in the waveguide in a direction perpendicular to the free face of the latter perpendicular to the X, Y plane.
[0144] A second variant of the first arm BR13 of an I3 interferometer of a C312 photonic sensor according to the third embodiment of the invention is described below with reference to the [ Fig. 12 ]. Common elements with those of the variant described in reference to the [ Fig. 11 ] are designated by the same references.
[0145] The SO3 optical system may include a converging lens L312. The converging lens L312 is intended to focus or collimate the light wave OL.
[0146] The L312 converging lens is, for example, an aspheric lens.
[0147] A third variant of the first BR13 arm of an I3 interferometer of a C313 photonic sensor according to the third embodiment of the invention is described below with reference to the [ Fig. 13 ]. Common elements with those of the variants described with reference to [ Fig. 11 ] And [ Fig. 12 ] are designated by the same references.
[0148] The SO3 optical system may include a converging lens L313. The converging lens L313 is intended to focus or collimate the light wave OL.
[0149] The L313 converging lens, for example, is a converging lens of any shape. The shape of the L313 converging lens can be chosen according to the DC3 coupling device.
[0150] The DC3 coupling device may include an RD313 diffraction grating.
[0151] The RD313 diffraction grating and the L313 converging lens can be configured so that the light extracted from the optical waveguide G13 propagates perpendicular or substantially perpendicular to the (X, Y) plane, even if the RD313 diffraction grating is configured to diffract a light wave propagating in the waveguide in a direction that is not perpendicular to the (X, Y) plane.
[0152] Optionally, in the three variants described above in relation to the [ Fig. 11 ], [ Fig. 12] et [Fig. 13 The reflective face F311 of the optical reflector R3 may be at least partially covered with a reflective layer, coating, or thin reflective film CR3. The reflective layer CR3 may include at least one metallic material, for example, gold. The reflective layer CR3 may be located opposite the coupling device DC3.
[0153] In all the embodiments considered, the second arm of the interferometer is isolated from the surrounding medium, for example by an oxide layer. The interferometric signal thus allows the volume refractive index of the surrounding medium to be determined.
[0154] In the case of a Mach-Zehnder interferometer, it is known that the noise 3σ of the phase variation measurement is on the order of φmin = 5 mrad at λ ≈ 850 nm. If we consider a propagation length of L = 6 mm, this allows us to measure changes in refractive index on the order of 1.1 × 10⁻⁷ RIU (RIU: dimensionless unit of measurement of the refractive index): Δn min = φ min λ / 2 π L = 1 , 1 10 − 7 RIU
[0155] This corresponds to the accuracy of very high-end scientific refractometers.
[0156] For comparison, a prior art Mach-Zehnder interferometer used as a biosensor and having a sensitive arm 1 cm long has a bulk limit of detection (LoD) of the order of 1 ×10 -6< RIU.
[0157] The invention has been described with reference to particular embodiments, but variations are possible. For example, different technological processes, other than those specifically mentioned, can be used for the manufacture of the coupling devices and the optical system directing the freely propagating light wave in the surrounding medium. Références
[0158] (Dietrich 2018) P.-I. Dietrich et al. « In situ 3D nanoprinting of free-form coupling elements for hybrid photonic integration », Nature Photonics, Vol. 12, avril 2018, pages 241 - 247. (Karlsson 1995) R. Karlsson et al. « Surface plasmon resonance detection and multispot sensing for direct monitoring of interactions involving low-molecular-weight analytes and for determination of low affinities ». Analytical biochemistry, 228(2), 274-280, 1995. (Ignatyeva 2021) D. Ignateyeva et al. « Sensing of Surface and Bulk Refractive Index Using Magnetophotonic Crystal with HybridMagneto-Optical Response »Sensors 2021, 21, 1984. (Laplatine 2022) L. Laplatine et al. « Silicon photonic olfactory sensor based on an array of 64 biofunctionalized Mach-Zender interferometers » Optics Express, Vol. 30, No. 19, 12 Sep. 2022. (Malinauskas 2012).M. Malinauskas et la.« 3D microoptical elements formed in a photostructurable germaniumsilicate by direct laser writing » Optics and Lasers in Engineering 50 (2012), 1785 - 1788. (Zhang 2019) Z. Zhang et al. « High-efficiency apodized bidirectional grating coupler for perfectly vertical coupling » Optics Letters, Vol. 44, No. 20, 15 octobre 2019.
Claims
1. Photonic sensor comprising an interferometer (11, 12, 13) having a first (BR1, BR12, BR13) and a second arm (BR2, BR23) comprising respective planar optical waveguides, wherein the first arm (BR1, BR12, BR13) comprises: - at least one first coupling device (DC1, DC12, DC3) between a guided propagation mode in a waveguide and a free propagation mode in an ambient environment (MA); and - an optical system (SO1, SO2, SO3) configured to direct said free propagation mode to said (DC3) or a second coupling device (DC2, DC22) between said free propagation mode in the ambient environment and a guided propagation mode in said or another waveguide; by means of which a lightwave (OL) passing through said first arm performs a part of its path in said ambient environment; characterised in that said or each said coupling device comprises a diffraction grating.
2. Photonic sensor according to claim 1, comprising a said second coupling device (DC2, DC22), distinct from said first coupling device (DC1, DC12), said first coupling device (DC1, DC12) being configured to extract said lightwave from the waveguide (G1, G12) and said second coupling device (DC2, DC22) to reinject it into said or said other waveguide (G1', G12), wherein said optical system (SO1, SO2) comprises a first and a second optical reflector, the first optical reflector (R1, R12) being configured to direct the lightwave extracted from the waveguide by the first coupling device (DC1, DC12) to the second optical reflector (R2, R22), which is itself configured to direct said lightwave to the second coupling device (DC2, DC22) reinjecting it into said or said other waveguide (G1, G12).
3. Photonic sensor according to claim 2, wherein the first (R1) and the second optical reflector (R2) are prisms (PR1, PR2, PR12, PR22, PR13, PR23, PR14, PR24) having: - a first face (F11, F21; F112, F212; F114, F214) opposite the first or the second coupling device, respectively; - a second face (F12, F22; F122, F222; F124, F224) inclined with respect to the first face, configured to reflect the lightwave and - a third face (F13, F23; F132, F232; F134, F234), the third faces of the first and of the second optical reflector being arranged opposite one another.
4. Photonic sensor according to claim 3, wherein the second face (F124, F224) of at least one of the first and of the second optical reflector is convex, to focus or collimate the lightwave by reflecting it.
5. Photonic sensor according to any one of claims 3 or 4, wherein the third face (F133, F233) of at least one of the first and of the second optical reflector is convex, so as to form a convergent lens to focus or collimate the lightwave by reflecting it.
6. Photonic sensor according to claim 2, wherein the first and the second optical reflector (R12, R22) are inclined faces (FI1, FI2) of a trench (T) obtained by anisotropic wet etching of a monocrystalline substrate (S2) forming, with the waveguide, a fluid conduit (CF) for said ambient environment.
7. Photonic sensor according to any one of the preceding claims, wherein said interferometer (11, 12) is of the Mach-Zehnder type.
8. Photonic sensor according to claim 1, wherein said interferometer (I3) is of the Michelson type, the first arm (BR13) having one single coupling device (DC3) configured to extract said lightwave from the waveguide (G13) and to reinject it into the waveguide after reflection by an optical reflector (R3) of said optical system (SO3), spaced apart from said coupling device (DC3).
9. Photonic sensor according to claim 1, wherein said second arm (BR2, BR23) has a surface being able to be brought into contact with said ambient environment (MA) and having a functionalization layer, enabling the specific binding of chemical or biological species.