CN114843290A - Method for manufacturing optical device and optical device - Google Patents

Abstract

Disclosed are a method for manufacturing an optical device and the optical device. The preparation method comprises the following steps: providing a transfer piece and an optical device to be transferred, wherein the transfer piece comprises a target transfer layer with a regular crystal orientation structure; forming a light-permeable medium layer on the surface of the optical device to be transferred; coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred; and, retaining at least a portion of the target transfer layer of the transfer member to form an optical device. Thus, the surface of the optical device manufactured by the specific manufacturing method as described above can form an optical layer structure having a regular crystal orientation structure.

Description

Method for manufacturing optical device and optical device

Technical Field

The present application relates to the field of semiconductor optics, and more particularly, to a method of fabricating an optical device and an optical device fabricated by the method.

Background

Silicon material is the most important semiconductor material at present, and simple substance silicon is a relatively active nonmetal element which can form silicide with 64 kinds of stable elements in 96 kinds of stable elements. The main use of silicon depends on its semiconductivity.

The mainstream preparation method of the polycrystalline silicon comprises the steps of firstly reducing silicon dioxide by using carbon to generate silicon, and then purifying by using hydrogen chloride to obtain the polycrystalline silicon with higher concentration; the mainstream production method of single crystal silicon is to produce polycrystalline silicon or amorphous silicon and then to produce rod-like single crystal silicon from the melt by the czochralski method or the suspension float zone method. Single crystal silicon is a crystal having a complete lattice structure in which the crystal orientation of silicon atoms is regular.

In some conventional optical devices, a layer of silicon crystal or silicon compound is formed on the surface of the optical device, for example, in the structural configuration of a spectrum chip, a layer of silicon crystal is formed on the surface of a photosensitive chip and is processed to obtain a light modulation layer, so as to modulate light passing through the light modulation layer. However, in the production process, since a process capable of forming a silicon crystal or silicide of a regular crystal orientation, such as the czochralski method or the suspension fusion method, is not suitable for forming a silicon crystal or silicide on an optical device, in the actual industry, a vapor deposition method is generally used to form a silicon crystal or silicide on a device. However, this method of preparation has a number of drawbacks.

First, the internal atoms of the silicon crystal or silicide obtained by the vapor deposition method are not regularly arranged, or the uniformity and regularity of the crystal orientation of the internal atoms of the silicon crystal or silicide obtained by the vapor deposition method are inferior to those of the silicon crystal or silicide formed by the czochralski method or the suspension float zone method.

Furthermore, for some optical devices with special requirements, the silicon crystal or silicide with incomplete rules may affect the performance of the optical device, i.e. it cannot be guaranteed that the performance of the manufactured optical device meets the preset requirements.

For example, in a conventional manufacturing process for a spectrum chip, a layer of silicon crystal is deposited on a photosensitive chip by a vapor deposition method and is processed to obtain a light modulation layer, thereby modulating light passing through the modulation layer. For a spectrum chip, the refractive index of the modulation layer is required to be as high as possible, so that the light loss is small due to high transmittance, and the transmittance of the modulation layer is low due to poor regularity of the crystal orientation of the atomic arrangement of the silicon crystal obtained by the vapor deposition method, so that the overall modulation effect of the modulation layer is deviated.

Therefore, there is a need for an optimized fabrication process for optical devices.

Disclosure of Invention

An advantage of the present application is to provide a method for manufacturing an optical device and an optical device, wherein the method for manufacturing an optical device migrates silicon crystals or silicides with preferred crystal orientation arrangement to a surface of an optical device to be transferred in a physical transfer-like manner, so that the surface of the optical device finally manufactured has an optical layer structure with preferred crystal orientation arrangement.

Other advantages and features of the present application will become apparent from the following description and may be realized by means of the instrumentalities and combinations particularly pointed out in the appended claims.

To achieve at least one of the above advantages, the present application provides a method of manufacturing an optical device, including:

providing a transfer piece and an optical device to be transferred, wherein the transfer piece comprises a target transfer layer with a regular crystal orientation structure;

forming a light-permeable medium layer on the surface of the optical device to be transferred;

coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred; and

leaving at least a portion of the target transfer layer of the transfer member to form an optical device.

In the method for manufacturing an optical device according to the present application, the upper surface of the light-permeable medium layer is a flat surface.

In the method for manufacturing an optical device according to the present application, forming a light-permeable medium layer on a surface of the optical device to be transferred includes: depositing the light-permeable medium layer on the surface of the optical device to be transferred by a vapor deposition process; and processing the upper surface of the light-permeable medium layer to enable the upper surface of the light-permeable medium layer to be a flat surface.

In the method for manufacturing an optical device according to the present application, before depositing the light-permeable medium layer on the surface of the optical device to be transferred by a vapor deposition process, the method further includes: and pretreating the surface of the optical device to be transferred to ensure that the part of the surface of the optical device to be transferred, which is used for depositing the light-permeable medium layer, is a flat surface.

In the method for manufacturing an optical device according to the present application, processing the upper surface of the light-permeable medium layer so that the upper surface of the light-permeable medium layer is a flat surface includes: and polishing and grinding the upper surface of the light-permeable medium layer by a chemical mechanical polishing process so as to enable the upper surface of the light-permeable medium layer to be a flat surface.

In the method of manufacturing an optical device according to the present application, the transfer member further includes a bonding layer formed on a surface of the target transfer layer, the bonding layer and the light-permeable medium layer having the same material of manufacture; wherein coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred comprises: coupling the transfer member to the optical device to be transferred in such a manner that the bonding layer formed on the surface of the target transfer layer is bonded to the light-permeable medium layer of the optical device to be transferred.

In a method of manufacturing an optical device according to the present application, coupling a transfer member to an optical device to be transferred in such a manner that a transfer target layer of the transfer member is bonded to a light-permeable medium layer of the optical device to be transferred, includes: forming a bonding layer on a surface of the target transfer layer of the transfer member, the bonding layer and the light-permeable medium layer having the same material; and coupling the transfer member to the optical device to be transferred in such a manner that the bonding layer formed on the surface of the target transfer layer is bonded to the light-permeable medium layer of the optical device to be transferred.

In the method of manufacturing an optical device according to the present application, forming a bonding layer on a surface of the target transfer layer of the transfer member includes: treating a surface of the target transfer layer to form the bonding layer on the surface of the target transfer layer of the transfer member, the bonding layer being made of the same material as the light-permeable medium layer.

In the method of manufacturing an optical device according to the present application, forming a bonding layer on a surface of the target transfer layer of the transfer member includes: and superposing the bonding layer on the surface of the target transfer layer, wherein the bonding layer and the light-permeable medium layer are made of the same material.

In a method of manufacturing an optical device according to the present application, retaining at least a portion of the target transfer layer of the transfer member to form an optical device, includes: removing portions of the transfer member other than the target transfer layer to leave the target transfer layer of the transfer member to form the optical device.

In a method of manufacturing an optical device according to the present application, retaining at least a portion of the target transfer layer of the transfer member to form an optical device, includes: removing portions of the transfer member other than the target transfer layer and at least a portion of the target transfer layer to leave at least a portion of the target transfer layer to form the optical device.

In the method of manufacturing an optical device according to the present application, the target transfer layer is a silicon crystal layer.

In the method of manufacturing an optical device according to the present application, the target transfer layer is a silicide layer.

In the method for manufacturing an optical device according to the present application, the optical device to be transferred is a semi-finished product of a spectrum chip, and the optical device is a spectrum chip.

In the method for manufacturing an optical device according to the present application, the semi-finished product of the spectrum chip comprises an image sensor and a signal processing circuit layer.

In a method of manufacturing an optical device according to the present application, retaining at least a portion of the target transfer layer of the transfer member to form an optical device, includes: forming a light modulating structure on the retained target-transferring layer to form the optical device.

In the method of manufacturing an optical device according to the present application, the target transfer layer of the transfer member has a light modulation structure formed therein.

In the method of manufacturing an optical device according to the present application, the transfer member is an SOI device, and the target transfer layer is a silicon crystal layer of the SOI device.

In a method of manufacturing an optical device according to the present application, there is provided a transfer member including: providing a monocrystalline silicon structure; and processing the single-crystal silicon structure to form the silicide layer within the single-crystal silicon structure to form the transfer.

In a method of manufacturing an optical device according to the present application, there is provided a transfer member including: providing a substrate layer; and, stacking the silicide layer on the base layer to form the transfer.

According to another aspect of the present application, there is also provided an optical device, wherein the optical device is manufactured in the manufacturing method as described above.

Further objects and advantages of the present application will become apparent from an understanding of the ensuing description and drawings.

These and other objects, features and advantages of the present application will become more fully apparent from the following detailed description, the accompanying drawings and the claims.

Drawings

The above and other objects, features and advantages of the present application will become more apparent by describing in more detail embodiments of the present application with reference to the attached drawings. The accompanying drawings are included to provide a further understanding of the embodiments of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the principles of the application. In the drawings, like reference numbers generally represent like parts or steps.

Fig. 1 illustrates a schematic diagram of an optical device according to an embodiment of the present application.

Fig. 2 illustrates a schematic diagram of a fabrication process of the optical device according to an embodiment of the present application.

Fig. 3 illustrates a flow chart of a method of making the optical device according to an embodiment of the present application.

Fig. 4A illustrates a schematic view of an example of a transfer member of a process of making an optical device according to an embodiment of the present application.

Fig. 4B illustrates a schematic view of another example of a transfer member of a process of manufacturing the optical device according to an embodiment of the present application.

Fig. 4C illustrates a schematic view of yet another example of a transfer member of a process of making an optical device according to an embodiment of the present application.

Fig. 4D illustrates a schematic view of yet another example of a transfer member of a process of making an optical device according to an embodiment of the present application.

Fig. 4E illustrates a schematic view of yet another example of a transfer member of a process of making an optical device according to an embodiment of the present application.

Fig. 5 illustrates a schematic view of a specific example 1 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 6 illustrates a schematic diagram of specific example 2 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 7 illustrates a schematic diagram of specific example 3 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 8 illustrates a schematic view of a variant implementation of the optical device and the method of manufacturing the optical device illustrated in specific example 3.

Fig. 9 illustrates a schematic view of another variant implementation of the optical device and the method of manufacturing the optical device illustrated in specific example 3.

Fig. 10 illustrates a schematic diagram of a specific example 4 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 11 illustrates a schematic view of another variant implementation of the optical device and the method of manufacturing the optical device illustrated in specific example 4.

Fig. 12 illustrates a schematic view of specific example 5 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 13 illustrates a schematic view of another variant implementation of the optical device and the method of manufacturing the optical device illustrated in specific example 5.

Fig. 14 and 15 are graphs showing comparison of the performance of the spectral chip manufactured according to the manufacturing methods illustrated in this specific example 3, specific example 4, and specific example 5 with that of an existing spectral chip.

Fig. 16 illustrates a schematic view of specific example 6 of the optical device and the method of manufacturing the optical device according to an embodiment of the present application.

Fig. 17 illustrates a schematic view of another modified implementation of the optical device and the method of manufacturing the optical device illustrated in specific example 6.

Fig. 18 illustrates a schematic view of an implementation of still another variation of the optical device and the method of manufacturing the optical device illustrated in specific example 6.

Fig. 19 illustrates a schematic view of the optical device and a further variant implementation of the method of manufacturing the optical device illustrated in specific example 6

Detailed Description

Hereinafter, example embodiments according to the present application will be described in detail with reference to the accompanying drawings. It should be understood that the described embodiments are only some embodiments of the present application and not all embodiments of the present application, and that the present application is not limited by the example embodiments described herein.

Summary of the application

As described above, in actual industries, a vapor deposition process is generally used to form silicon crystals or silicon compounds on the surface of an optical device to form an optical layer structure. However, the silicon crystals and/or silicon compounds formed by vapor deposition often have irregular or not completely regular internal crystal orientation, which results in poor optical properties of the silicon crystals and/or silicon compounds obtained by vapor deposition and thus cannot meet the application requirements. In particular, the optical layer structure formed by the vapor deposition process has technical problems of low light transmittance, low refractive index, and the like.

Meanwhile, as described above, in a semiconductor process, silicon crystals obtained by a process such as the czochralski method or the suspension fusion method have a very regular arrangement of internal atoms, that is, have a relatively high regularity of crystal orientation, and further, silicon compounds (e.g., silicon dioxide, silicon nitride, etc.) are produced on the basis of the silicon crystals, and have a regular internal crystal orientation. However, due to the limitations of the process itself, the czochralski method or the suspension fusion method cannot be directly applied to the manufacturing process for forming the optical layer structure on the surface of the optical device.

Based on this, the inventors of the present application conceived: whether existing silicon crystals and/or silicon compounds with regular internal crystal orientation can be migrated to the surface of the optical device through a specific preparation process to form a target optical layer structure, so that the performance of the finally obtained optical device can be ensured.

Based on this, the present application provides a method of manufacturing an optical device, comprising: providing a transfer piece and an optical device to be transferred, wherein the transfer piece comprises a target transfer layer with a regular crystal orientation structure; forming a light-permeable medium layer on the surface of the optical device to be transferred; coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred; and, retaining at least a portion of the target transfer layer of the transfer member to form an optical device. In this way, the preparation method transfers the silicon crystals or the silicides with better crystal orientation arrangement to the surface of the optical device to be transferred in a physical transfer-like manner, so that the surface of the finally prepared optical device has an optical layer structure with better crystal orientation arrangement.

Having described the general principles of the present application, various non-limiting embodiments of the present application will now be described with reference to the accompanying drawings.

Exemplary optical devices and methods of making the same

As shown in fig. 1, an optical device 100 according to an embodiment of the present application is illustrated, wherein the optical device 100 includes an optical device body 110 and an optical layer structure 120 formed on a surface of the optical device body 110 by a specific manufacturing process. In particular, the optical layer structure 120 has a regular crystal orientation structure, that is, the arrangement of atoms inside the optical layer structure 120 is regular, and therefore, the optical layer structure 120 has excellent performance (e.g., has superior refractive index, throw ratio, etc.), so that when the optical layer structure 120 is bonded to the surface of the optical device body 110, it can provide good performance support for the optical device body 110, so that the optical device 100 can meet application requirements.

As shown in fig. 1, in the embodiment of the present application, the optical device 100 further includes a coupling layer 130 formed between the optical device body 110 and the optical layer structure 120, so that the optical layer structure 120 is stably combined with the optical device body 110 through the coupling layer 130 to form the complete optical device 100.

Specifically, in the embodiment of the present application, the coupling layer 130 includes a light-permeable medium layer 131 disposed on the surface of the optical device main body 110, wherein the upper surface of the light-permeable medium layer 131 is a flat surface, so that the portion of the optical device main body 110 combined with the optical layer structure 120 is a flat surface through the light-permeable medium layer 131, so as to facilitate the combination between the optical device main body 110 and the optical layer structure 120. Further, as shown in fig. 1, the coupling layer 130 further includes a bonding layer 132 disposed on the surface of the optical layer structure 120, wherein the bonding layer 132 and the light-permeable medium layer 131 have good bonding reaction therebetween, for example, in the specific example of the present application, the bonding layer 132 and the light-permeable medium layer 131 may be made of the same material (for example, made of silicide) so that the bonding layer 132 and the light-permeable medium layer 131 have good bonding reaction therebetween. Accordingly, when the bonding layer 132 is bonded to the light-permeable medium layer 131, a high bonding force is formed between the bonding layer 132 and the light-permeable medium layer 131, so that the optical device body 110 and the optical layer structure 120 form a stable bonding relationship.

More specifically, in the embodiments of the present application, the type of the optical device 100 is not limited to the present application, and includes but is not limited to: active optical components (e.g., VCSEL chips, etc.), passive optical components (e.g., spectroscopic chips, CCD photosensing chips, CMOS photosensing chips, etc.), and the like. Accordingly, the optical device body 110 may be implemented as a semi-finished product of the optical device 100 (e.g., a semi-finished product of a spectrum chip), that is, the optical device body 110 itself may be an incomplete product, and of course, in some examples of the present application, the optical device body 110 itself may be implemented as an integral product, and the optical layer structure 120 is equivalent to optimizing the function of the product or performing a function superposition on the basic function of the product, which is not limited by the present application.

The optical layer structure 120 is a silicon crystal layer, a silicide layer or a bonding layer 132 of the silicon crystal layer and the silicide layer having a regular crystal orientation structure, and is formed on the surface of the optical device main body 110 through a specific preparation process, so as to provide specific functional support for the optical device main body through the optical layer structure 120. In a specific example, the optical layer structure 120 may be configured to have an optical modulation function, for example, when the optical device 100 is a spectrum chip, the optical layer structure 120 may be configured to have an optical modulation structure to modulate the imaging light entering the spectrum chip; for another example, when the optical device 100 is a VCSEL chip, the optical layer structure 120 may be configured to have a light diffusion function to perform diffusion modulation on the emitted laser light. Of course, in other examples, the optical layer structure 120 also serves as a protective layer to prevent the optical device 100 from being scratched, from being too exposed to the environment, and serves as an insulation, which is not limited in this application.

As described above, in the manufacturing process, since a process capable of forming silicon crystals or silicides of regular crystal orientations, such as the czochralski method or the suspension fusion method, is not suitable for forming silicon crystals or silicides on the optical device 100, in the actual industry, the vapor deposition method is generally used to form silicon crystals or silicides on the device. However, the internal atoms of the silicon crystal or silicide obtained by the vapor deposition method are not regularly arranged, and therefore, for some optical devices 100 with special requirements, the silicon crystal or silicide which is not completely regular cannot ensure that the performance of the manufactured optical device 100 meets the preset requirements. For example, in the existing manufacturing process for a spectrum chip, a layer of silicon crystal is deposited on a photosensitive chip by a vapor deposition method and is processed to obtain a light modulation structure, so as to modulate light passing through the modulation layer. For a spectrum chip, the refractive index of the modulation layer is required to be as high as possible, so that the light loss is small due to high transmittance, and the transmittance of the modulation layer is low due to poor regularity of the crystal orientation of the atomic arrangement of the silicon crystal obtained by the vapor deposition method, so that the overall modulation effect of the modulation layer is deviated.

Accordingly, in the embodiment of the present application, the optical device 100 is manufactured by a specific manufacturing method, wherein the manufacturing method migrates silicon crystals or silicides with a preferred crystal orientation arrangement to the surface of the optical device 100 to be transferred in a physical transfer-like manner, so that the surface of the optical device 100 finally manufactured has the optical layer structure 120 with a preferred crystal orientation arrangement.

Fig. 2 illustrates a schematic diagram of a fabrication process of the optical device 100 according to an embodiment of the present application. Fig. 3 illustrates a flow chart of a method of fabricating the optical device 100 according to an embodiment of the present application.

As shown in fig. 2 and 3, the method for manufacturing the optical device 100 according to the embodiment of the present application includes the steps of: s110, providing a transfer piece 200 and an optical device 300 to be transferred, wherein the transfer piece 200 comprises a target transfer layer 210 with a regular crystal orientation structure; s120, forming a light-permeable medium layer 310 on the surface of the optical device 300 to be transferred; s130, coupling the transfer member 200 to the optical device 300 to be transferred in a manner that the transfer target layer 210 of the transfer member 200 is bonded to the light-permeable medium layer 310 of the optical device 300 to be transferred; and, S140, leaving at least a portion of the target transfer layer 210 of the transfer member 200 to form an optical device.

In step S110, a transfer member 200 and an optical device 300 to be transferred are provided, wherein the transfer member 200 includes a target transfer layer 210 having a regular crystal orientation structure. Accordingly, in the present embodiment, the optical device 300 to be transferred is the optical device body 110 as described above, which is a body portion of the optical device. The transfer member 200 includes a target transfer layer 210 having a regular crystal orientation structure, that is, the transfer member 200 includes an optical layer structure having a regular crystal orientation structure.

Accordingly, the technical key of the preparation method according to the embodiment of the application is that: the target transfer layer 210 of the transfer member 200 is migrated to the surface of the optical device 300 to be transferred. In the migration process, not only how to migrate the target transfer layer 210 to the surface of the optical device 300 to be transferred, but also: what structure the transfer member 200 with the target transfer layer 210 has, how to prepare the transfer member 200 with the target transfer layer 210, how to ensure that the target transfer layer 210 can be stably and conformably bonded to the surface of the optical device 300 to be transferred, if the transfer member 200 includes other structures than the target transfer layer 210, how to remove the unnecessary portions of the transfer member 200 after bonding the transfer member 200 to the surface of the optical device 300 to be transferred, and the like.

As described above, in the embodiment of the present application, the optical layer structure is the silicon crystal layer 213 or the silicide layer 212 having a regular crystal orientation structure. Accordingly, in the embodiment of the present application, the target transfer layer 210 of the transfer member 200 is a silicon crystal layer 213 or a silicide layer 212.

In a specific implementation, the transfer member 200 may include only the target transfer layer 210, i.e., the transfer member 200 itself is the target transfer layer 210, i.e., the transfer member 200 is a silicon crystal layer 213 (or a silicon substrate layer 211) or a silicide layer 212. It will be appreciated by those skilled in the art that in the semiconductor field, it is common to use a single crystal silicon substrate as a substrate and form other components on the substrate, and rarely to use it directly as pure single crystal silicon or pure silicide. Accordingly, in the practice of the present application, the transfer member 200 generally comprises a layer structure other than the transfer target layer 210.

Specifically, when the target transfer layer 210 is a Silicon crystal layer 213, the transfer member 200 may be selected as an existing SOI device (Silicon on insulator). That is, in the manufacturing method according to the embodiment of the present application, a device including the transfer target layer 210, which is now produced, may be used as the transfer member 200, so that on the one hand, the cost can be reduced, and on the other hand, the existing device has already developed its technology and has stable and predictable performance.

Fig. 4A illustrates a schematic view of an example of a transfer member 200 of a process of making an optical device according to an embodiment of the present application. As shown in fig. 4A, the transfer member 200 is implemented as an existing SOI device, which includes, in order from bottom to top: a silicon base layer 211, a silicide layer 212, and a silicon crystal layer 213, wherein the silicon crystal layer 213 positioned uppermost is the target transfer layer 210.

Of course, when the target transfer layer 210 is the silicon crystal layer 213, the transfer member 200 may be an existing device, that is, the transfer member 200 is a self-made device. Fig. 4B illustrates a schematic view of another example of a transfer member 200 of a process of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 4B, the transfer member 200 is implemented as a homemade device, which includes a silicon base layer 211 and a silicide layer 212 from bottom to top, wherein the silicon base layer 211 is the target transfer layer 210.

Specifically, the transfer member 200 as illustrated in fig. 4B may be prepared in the following manner. Specifically, first, a single crystal silicon structure is provided, for example, by a process such as the czochralski method or the suspension fusion method. The single-crystal silicon structure is then processed to form the silicide layer 212 within the single-crystal silicon structure to form the transfer 200, for example, anions (e.g., oxygen ions or nitrogen ions) are implanted within the single-crystal silicon structure to form the silicide layer 212 within the single-crystal silicon structure. Accordingly, after the anions are implanted, the portion of the single crystalline structure that is not implanted with the anions, including but not limited to oxygen ions, nitrogen ions, etc., forms the silicon substrate layer 211, and the portion implanted with the anions forms the silicide layer 212.

It is understood that the arrangement of the atoms in the single-crystal silicon structure obtained by the Czochralski method or the suspension fusion method is very regular, that is, has relatively high regularity of crystal orientation, and further, the silicon compound is prepared by using the single-crystal silicon as a base, and the crystal orientation in the silicon compound is also regular.

Of course, the transfer member 200 as illustrated in fig. 4B may be prepared in other ways. For example, first, a silicon substrate layer 211 is provided, and similarly, the silicon substrate layer 211 can be obtained by a process such as a czochralski method or a float zone method. Then, the silicide layer 212 is stacked on the base layer by an adhesive to form the transfer 200.

Accordingly, when the target transfer layer 210 is the silicide layer 212, the transfer member 200 may also be implemented as the structure illustrated in fig. 4B, that is, the transfer member 200 includes a silicon base layer 211 and a silicide layer 212 formed on the silicon base layer 211, wherein the silicide layer 212 is the target transfer layer 210, as shown in fig. 4C.

As previously mentioned, in some examples of the present application, the optical layer structure of the optical device may be configured to have an optical modulation function, for example, when the optical device is a spectral chip, the optical layer structure may be configured to have an optical modulation structure to modulate imaging light entering the spectral chip. Accordingly, in these examples, the light modulating structure may be pre-fabricated to the target transfer layer 210 of the transfer member 200. For example, when the target transfer layer 210 is a silicon crystal layer 213, the silicon crystal layer 213 of the SOI device illustrated in fig. 4A may be processed to form a light modulating structure 201 within the silicon crystal layer 213 to form the transfer device 200 illustrated in fig. 4D. Of course, when the target transfer layer 210 is the silicon crystal layer 213, the target transfer layer 210 of the transfer device 200 illustrated in fig. 4B may also be processed so that the target transfer layer 210 has the light modulation structure 201 to form the transfer device 200 illustrated in fig. 4E.

In the embodiment of the present application, the transfer target layer 210 of the transfer member 200 may also be processed in the subsequent step S140 to form the optical modulation structure, which is not limited in the present application.

In step S120, a light-permeable medium layer 310 is formed on the surface of the optical device 300 to be transferred. Here, the light-permeable medium layer 310 may be made of a transparent material, such as silicide (including but not limited to silicon dioxide, silicon nitride, etc.). The light-permeable medium layer 310 can be integrally formed on the surface of the optical device 300 to be transferred by a non-metal vapor deposition process. Of course, in other examples of the present application, other processes may be used to form the light-permeable medium layer 310 on the surface of the optical device 300 to be transferred, such as bonding, attaching, and the like.

In particular, in the embodiment of the present application, the upper surface of the light-permeable medium layer 310 is a flat surface. It should be understood that, in the embodiment of the present application, the portion where the optical device 300 to be transferred is combined with the transfer member 200 is the upper surface of the light-permeable medium layer 310, so that, when the upper surface of the light-permeable medium layer 310 is a flat surface, it is equivalent to that the optical device 300 to be transferred forms a flat combined surface on the outer surface thereof, so as to facilitate stable combination between the optical device 300 to be transferred and the target transfer layer 210 of the transfer member 200.

Of course, in specific implementations, the surface of the optical device 300 to be transferred may be non-flat, and the upper surface of the light-permeable medium layer 310 may also be non-flat, so in some examples of the present application, the process of forming a light-permeable medium layer 310 on the surface of the optical device 300 to be transferred includes: first, the surface of the optical device 300 to be transferred is pretreated so that the portion of the surface of the optical device 300 to be transferred, on which the light-permeable medium layer 310 is deposited, is a flat surface, which facilitates the formation of the light-permeable medium layer 310 on the surface of the optical device 300 to be transferred. Next, the light-permeable medium layer 310 is deposited on the surface of the optical device 300 to be transferred by a vapor deposition process. Then, the upper surface of the light-permeable medium layer 310 is processed to make the upper surface of the light-permeable medium layer 310 a flat surface.

In a specific implementation, the step of processing the upper surface of the light-permeable medium layer 310 to make the upper surface of the light-permeable medium layer 310 be a flat surface includes: the upper surface of the light-permeable medium layer 310 is polished by a Chemical Mechanical polishing process (CMP) so that the upper surface of the light-permeable medium layer 310 is a flat surface.

It is worth mentioning that, in some of the to-be-transferred optical devices 300 of the present application, if the surface of the to-be-transferred optical device 300 is a flat surface, the light-permeable medium layer 310 may not be formed on the surface of the to-be-transferred optical device 300, that is, in some specific examples of the present application, the step S120 may not be performed.

In step S130, the transfer member 200 is coupled to the optical device 300 to be transferred in such a manner that the transfer target layer 210 of the transfer member 200 is bonded to the light-permeable medium layer 310 of the optical device 300 to be transferred. That is, in the embodiment of the present application, the transfer member 200 is stably coupled to the optical device 300 to be transferred in a bonding process.

In order to ensure the bonding effect, it is preferable that the surface of the transfer member 200 bonded to the light-permeable medium layer 310 can generate a good bonding reaction with the light-permeable medium layer 310, so that the overall bonding force is greater, and the overall reliability is ensured. It will be appreciated by those skilled in the art that the bonding effect between the same materials is better, therefore, in the embodiment of the present application, before the target transfer layer 210 of the transfer member 200 is bonded to the light-permeable medium layer 310 of the optical device 300 to be transferred, a bonding layer made of the same material as the light-permeable medium layer 310 is preferably disposed on the surface of the target transfer layer 210 of the transfer member 200.

In one particular example of the present application, the bonding layer may be pre-fabricated on the transfer member 200 target transfer layer 210, i.e., in this particular example, the bonding layer is part of the transfer member 200 itself. In this way, the bonding layer formed on the surface of the target transfer layer 210 is bonded to the light-permeable medium layer 310 of the optical device to be transferred 300 during the process of bonding the target transfer layer 210 of the transfer member 200 to the light-permeable medium layer 310 of the optical device to be transferred 300, so that the transfer member 200 is stably coupled to the optical device to be transferred 300.

In another specific example of the present application, the bonding layer 220 may be formed on the surface of the transfer target layer 210 of the transfer member 200 prior to bonding the transfer target layer 210 of the transfer member 200 to the light-permeable medium layer 310 of the optical device 300 to be transferred. In a specific implementation, the bonding layer 220 may be formed on the upper surface of the target transfer layer 210 of the transfer member 200 by treating the surface of the target transfer layer 210, the bonding layer 220 being made of the same material as the light-permeable medium layer 310. For example, when the light-permeable medium layer 310 is a silicon dioxide layer, oxygen ions can be implanted into the upper surface of the transfer target layer 210 to form the bonding layer 220 on the surface of the transfer target layer 210 of the transfer member 200, wherein the bonding layer 220 is made of silicon dioxide. Of course, in other embodiments, the bonding layer 220 may be formed on the upper surface of the target transfer layer 210 in an overlapping manner, and the bonding layer 220 and the light-permeable medium layer 310 may be made of the same material, which is not limited in this application.

In step S140, at least a portion of the target transfer layer 210 of the transfer member 200 is retained to form an optical device. It should be understood that the target transfer layer 210 is an optical layer structure that is desirable for the optical device, and therefore, in the embodiment of the present application, if the transfer member 200 includes other layer structures besides the target transfer layer 210, it is necessary to remove unnecessary portions of the transfer member 200 and to retain at least a portion of the target transfer layer 210 of the transfer member 200.

In a specific implementation, if the target transfer layer 210 is a silicon crystal layer 213 and the transfer member 200 is implemented as the structure illustrated in fig. 4A, the process of retaining at least a portion of the target transfer layer 210 of the transfer member 200 in step S140 includes: the silicon base layer 211 and the silicide layer 212 of the transfer 200 are removed to completely leave the transfer-target layer 210. That is, the silicon base layer 211 and the silicide layer 212 of the transfer 200 are removed, and the target transfer layer 210 is completely remained. Of course, in the specific implementation, in order to meet the thickness dimension requirement, a part of the silicon crystal layer 213 may be further removed, which is not limited in this application.

Those skilled in the art will appreciate that the silicide layer 212 in the transfer 200 has stable physical and chemical properties, and thus, in an implementation, a portion of the silicide layer 212 may be retained to protect the silicon crystal layer 213 (the transfer target layer 210) by the silicide layer 212.

In a specific implementation, if the target transfer layer 210 is a silicon crystal layer 213 and the transfer member 200 is implemented as the structure illustrated in fig. 4B, at least a portion of the target transfer layer 210 of the transfer member 200 is retained in step S140 to form an optical device, including: the silicide layer 212 of the transfer member 200 is removed to leave the transfer-target layer 210. That is, the silicide layer 212 of the transfer 200 is removed, and the silicon crystal layer 213 is completely remained. Those skilled in the art will appreciate that the silicide layer 212 in the transfer 200 has stable physical and chemical properties, and thus, in an implementation, a portion of the silicide layer 212 may be retained to protect the silicon crystal layer 213 (the transfer target layer 210) by the silicide layer 212.

In an implementation, if the transfer target layer 210 is a silicide layer 212 and the transfer 200 is implemented as the structure illustrated in fig. 4B, the process of retaining at least a portion of the transfer target layer 210 of the transfer 200 in step S140 includes: the silicon base layer 211 of the transfer member 200 is removed to leave the target transfer layer 210. That is, the silicon base layer 211 of the transfer 200 is removed, leaving the silicide layer 212 entirely.

In the above implementation, mechanical grinding, chemical mechanical polishing, etching process, etc. may be used to remove the portion of the transfer member 200 that needs to be removed. Of course, those skilled in the art will appreciate that mechanical grinding is efficient but not precise, and that chemical mechanical polishing and etching processes are slow but precise, so that in a particular process, mechanical grinding can be used to perform rough machining before chemical mechanical polishing or etching to perform finish machining to achieve both efficiency and precision.

As previously mentioned, in some examples of the present application, the optical layer structure of the optical device may be configured to have an optical modulation function, for example, when the optical device is a spectral chip, the optical layer structure may be configured to have an optical modulation structure 201 to modulate imaging light entering the spectral chip.

Accordingly, in these examples, after retaining at least a portion of the transfer target layer 210 of the transfer member 200, the retained transfer target layer 210 may be further processed to form the light modulating structure 201 within the transfer target layer 210. For example, when the transfer member 200 is the structure illustrated in fig. 4A, after the silicon base layer 211 and the silicide layer 212 of the transfer member 200 are removed to leave at least a portion of the silicon crystal layer 213, the silicon crystal layer 213 is further processed by an etching process, a nanoimprint process, or the like to form the light modulation structure 201.

The specific process flow of the nano silk-screen printing process is as follows: firstly, coating a photosensitive material (such as photoresist) on the surface of a metal film on a wafer; then, a template having a filter pattern engraved thereon is pressed, and particularly, the template is transparent; then, ultraviolet light (UV light) is irradiated thereto to harden the photoresist on which the template pattern has been printed. The patterned photoresist is then visible by stripping the template.

That is, in some examples of the present application, the process of retaining at least a portion of the transfer target layer 210 of the transfer member 200 further comprises: forming a light modulating structure 201 on the retained object transfer layer 210 to form the optical device.

Of course, in some examples of the present application, if the light modulating structure 201 is pre-fabricated within the transfer target layer 210 of the transfer member 200, the light modulating structure is also simultaneously retained in retaining at least a portion of the transfer target layer 210 of the transfer member 200.

In summary, the method for manufacturing the optical device according to the embodiments of the present application is illustrated, which migrates the silicon crystals or silicides with a preferred crystal orientation arrangement to the surface of the optical device 300 to be transferred in a physical-like manner, so that the surface of the optical device finally manufactured has an optical layer structure with a preferred crystal orientation arrangement.

Concrete example 1

Fig. 5 illustrates a schematic diagram of one specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 5, in this particular example, the preparation method is aimed at: a silicon crystal layer 213 having a regular crystal orientation structure is formed on the surface of the optical device.

As shown in fig. 5, in this specific example, the optical device manufacturing process includes first pre-treating the surface of the optical device 300 to be transferred to form a flat bonding surface for bonding the transfer member 200 on the surface of the optical device 300 to be transferred.

Specifically, in this specific example, the process of pretreating the surface of the optical device 300 to be transferred includes: a light-permeable medium layer 310 is formed on the surface of the optical device 300 to be transferred, wherein the light-permeable medium layer 310 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the optical device 300 to be transferred. In this specific example, the material of the light-permeable medium layer 310 is preferably silicide, such as silicon dioxide, silicon nitride, etc. In a specific implementation, the light-permeable medium layer 310 can be formed on the surface of the optical device 300 to be transferred by a non-metal vapor deposition process, for example, but in other embodiments of this specific implementation, the light-permeable medium layer 310 can also be formed by other processes, and the formation process is not limited in this application.

As shown in fig. 5, in this specific example, the upper surface of the light-permeable medium layer 310 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 310 for combining with the transfer member 200 has a relatively high flatness, so as to facilitate the transfer member 200 to the optical device 300 to be transferred.

It is worth mentioning that in some cases of this particular example, the surface of the optical device 300 to be transferred may be non-flat, and the upper surface of the light-permeable medium layer 310 formed on the surface of the optical device 300 to be transferred by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the optical device 300 to be transferred, and/or polishing and grinding the upper surface of the light-permeable medium layer 310. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

As shown in fig. 5, the process of manufacturing the optical device further includes: a transfer member 200 is provided. In particular, in this specific example, the transfer member 200 is an SOI device (Silicon on insulator, Silicon device) which includes, in order from bottom to top: a silicon base layer 211, a silicide layer 212 and a silicon crystal layer 213, wherein the silicon crystal layer 213 is the target transfer layer 210 of the transfer object 200, that is, in this specific example, the target transfer layer 210 of the transfer object 200 is located at the uppermost layer of the transfer object 200. It will be appreciated by those skilled in the art that the SOI device is an existing device, and the existing device including the target transition layer 210 is used as the transition member 200, so that the cost can be reduced on the one hand, and the existing device has developed the technology and has stable and predictable performance.

Also, as will be appreciated by those skilled in the art, in the SOI device, the arrangement of atoms in the silicon base layer 211, the silicide layer 212 and the silicon crystal layer 213 are regular, i.e., all three have a good crystal orientation structure.

Preferably, in this particular example, the surface of the silicon crystal layer 213 is a flat surface.

As shown in fig. 5, the process of manufacturing the optical device further includes: the SOI device is coupled to the to-be-transferred optical device 300 in such a way that the upper surface of the SOI device is bonded to the upper surface of the light-permeable medium layer 310 of the to-be-transferred optical device 300. That is, the SOI device is transferred to the optical device to be transferred 300 in such a manner that the surface of the silicon crystal layer 213 of the SOI device is bonded to the upper surface of the light-permeable medium layer 310 of the optical device to be transferred 300.

In order to ensure the bonding strength between the SOI device and the optical device 300 to be transferred, preferably, in the embodiment of the present application, the upper surface of the SOI device preferably has a good bonding reaction with the light-permeable medium layer 310, so that the two can generate a good bonding reaction when bonded, and generate a greater bonding force. For example, in this particular example, the upper surface of the SOI device and the light-permeable medium layer 310 are made of the same material, so that the two can generate a good bonding reaction during bonding, resulting in a larger bonding force.

Taking the light-permeable dielectric layer 310 as silicon dioxide for example, it should be understood that the upper surface of the SOI device is formed by the surface of the silicon crystal layer 213. Thus, in this implementation, before bonding the upper surface of the SOI device to the upper surface of the light-permeable medium layer 310, further comprises: treating the upper surface of the SOI device such that the upper surface of the SOI device is made of a silicon dioxide material.

In a specific implementation, oxygen ions may be implanted into the surface of the silicon crystal layer 213 to form a silicon dioxide layer on the surface portion of the silicon crystal layer 213, so that the upper surface of the SOI device is formed of silicon dioxide. It should be understood that the silicon crystal layer 213 has a regular crystal orientation structure, and therefore, the silicon dioxide layer also has a regular crystal orientation structure, so as to improve the bonding effect with the light-permeable medium layer 310.

Of course, in other embodiments of this specific example, a bonding layer 220 may be further stacked on the surface of the silicon crystal layer 213, wherein the bonding layer 220 is made of a silicon dioxide material, and the bonding layer 220 is formed by, for example, a non-metal vapor deposition process by stacking on the surface of the silicon crystal layer 213, so as to improve the bonding strength between the transfer member 200 and the optical device 300 to be transferred by the bonding layer 220.

It should be noted that, in this specific example, the process of processing the upper surface of the SOI device may also be completed in the step of providing the transfer member 200, and this is not a limitation of the present application.

As shown in fig. 5, the process of manufacturing the optical device further includes: the silicon base layer 211 is removed and at least a portion of the silicide layer 212 and the silicon crystal layer 213 remain. In this particular example, the silicon base layer 211 may be removed by one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes.

It is worth mentioning that the mechanical grinding has high efficiency but poor precision, while the chemical mechanical polishing and etching processes have low efficiency but high precision, so in this specific example, it is preferable that the silicon substrate layer 211 is first processed by the mechanical grinding and polishing, and then the silicon substrate layer 211 is processed by the chemical mechanical polishing or etching process in the second stage, so that the processed surface is a flat surface. In this particular example, the silicon crystal layer 213 has a regular atomic arrangement crystal orientation, which can ensure the performance of the optical device, while the silicide layer 212 remains, and the silicon crystal layer 213 can be protected by the stability of the silicide layer 212.

In other embodiments of this specific example, the process for manufacturing the optical device further includes: the silicide layer 212 is removed so that the silicon crystal layer 213 is exposed, that is, the transfer member 200 is further processed so that portions of the transfer member 200 other than the target transfer layer 210 are removed so that the target transfer layer 210 is left. It should be understood that since the silicon crystal layer 213 is formed by the czochralski method, the internal atoms are arranged in a regular crystal orientation, and the internal structure of the silicon crystal layer 213 is not changed during the transfer member 200 is transferred, the silicon crystal layer 213 finally formed on the surface of the optical device has a regular crystal orientation structure.

In other embodiments of this specific example, the process for manufacturing the optical device further includes: at least a portion of the remaining silicon crystal layer 213 is removed, that is, the remaining silicon crystal layer 213 is further processed to thin the silicon crystal layer 213.

In summary, the optical device and the method for manufacturing the same based on this specific example are illustrated, which migrate the silicon crystal layer 213 having a preferred crystal orientation arrangement to the surface of the optical device 300 to be transferred in a specific manufacturing method, so that the surface of the optical device finally manufactured has an optical layer structure having a preferred crystal orientation arrangement.

Concrete example 2

Fig. 6 illustrates a schematic view of another specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 6, in this specific example, the preparation method is aimed at: a silicide layer 212 (e.g., a silicon dioxide layer or a silicon nitride layer) having a regular crystal orientation structure is formed on a surface of the optical device to provide protection to the optical device through the silicide layer 212, such as insulation, scratch prevention, overexposure prevention, and the like.

As shown in fig. 6, in this specific example, the optical device manufacturing process includes first pre-treating the surface of the optical device 300 to be transferred to form a flat bonding surface for bonding the transfer member 200 on the surface of the optical device 300 to be transferred.

Specifically, in this specific example, the process of pretreating the surface of the optical device 300 to be transferred includes: a light-permeable medium layer 310 is formed on the surface of the optical device 300 to be transferred, wherein the light-permeable medium layer 310 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the optical device 300 to be transferred. In this specific example, the material of the light-permeable medium layer 310 is preferably silicide, such as silicon dioxide, silicon nitride, etc. In a specific implementation, the light-permeable medium layer 310 can be formed on the surface of the optical device 300 to be transferred by a non-metal vapor deposition process, for example, but in other embodiments of this specific implementation, the light-permeable medium layer 310 can also be formed by other processes, and the formation process is not limited in this application.

As shown in fig. 6, in this specific example, the upper surface of the light-permeable medium layer 310 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 310 for combining with the transfer member 200 has a relatively high flatness, so as to facilitate the transfer member 200 to the optical device 300 to be transferred.

It is worth mentioning that in some cases of this particular example, the surface of the optical device 300 to be transferred may be non-flat, and the upper surface of the light-permeable medium layer 310 formed on the surface of the optical device 300 to be transferred by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the optical device 300 to be transferred, and/or polishing and grinding the upper surface of the light-permeable medium layer 310. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

As shown in fig. 6, the process of manufacturing the optical device further includes: a transfer member 200 is provided. In particular, in this specific example, the transfer member 200 is a self-made semiconductor device (Silicon on insulator, Silicon device) which includes, in order from bottom to top: a silicon base layer 211 and a silicide layer 212 formed on the silicon base layer 211, wherein the silicide layer 212 is a target transfer layer 210 of the to-be-transferred piece 200, that is, in this specific example, the target transfer layer 210 of the to-be-transferred piece 200 is located at the uppermost layer of the to-be-transferred piece 200.

In particular, in the present embodiment, the crystal orientation arrangement of atoms in the silicide layer 212 (i.e., the transfer target layer 210) is regular. In one implementation of this particular example, the homemade transfer member 200 may be prepared as follows: firstly, forming a monocrystalline silicon structure with a regular crystal orientation structure by a Czochralski method, a suspension zone melting method or other processes; further, a portion of the single-crystal silicon structure is processed to obtain the silicide layer 212, wherein the unprocessed portion of the single-crystal silicon structure forms the silicon base layer 211, for example, when the silicide layer 212 is a silicon dioxide layer, oxygen ions may be implanted at a corresponding position of the single-crystal silicon structure to form the silicon dioxide layer. It should be appreciated that because the atoms within the single crystal silicon structure have a regular distribution of crystal orientations, the silicide layer 212 has a regular structure of crystal orientations, as does the silicon base layer 211.

It is worth mentioning that in this specific example, the surface of the silicon crystal layer 213 is a flat surface.

As shown in fig. 6, the process of manufacturing the optical device further includes: the transfer member 200 is coupled to the to-be-transferred optical device 300 in such a manner that the upper surface of the transfer member 200 is bonded to the upper surface of the light-permeable medium layer 310 of the to-be-transferred optical device 300. That is, the transfer member 200 is transferred to the to-be-transferred optical device 300 in such a manner that the upper surface of the silicide layer 212 of the transfer member 200 is bonded to the upper surface of the light-permeable medium layer 310 of the to-be-transferred optical device 300.

In order to ensure the bonding strength between the transfer member 200 and the optical device 300 to be transferred, preferably, in the embodiment of the present application, the upper surface of the transfer member 200 and the upper surface of the light-permeable medium layer 310 have good bonding reaction, so that the two can generate good bonding reaction when bonded to generate a larger bonding force. For example, in this particular example, the upper surface of the transfer member 200 and the light-permeable medium layer 310 are made of the same material, so that the two can generate a good bonding reaction and generate a larger bonding force when bonding.

In this example, the upper surface of the transfer member 200 is formed of the upper surface of the silicide layer 212, and the light-permeable medium layer 310 is also formed of silicide, so that when the silicide layer 212 of the transfer member 200 is in conformity with the kind of silicide of the light-permeable medium layer 310, the upper surface of the transfer member 200 and the upper surface of the light-permeable medium layer 310 have a good bonding reaction to generate a greater bonding force when they are bonded.

As shown in fig. 6, the process of manufacturing the optical device further includes: the silicide layer 212 remains. In this particular example, the silicon base layer 211 may be removed using one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes, such that the silicide layer 212 remains. Accordingly, in this particular example, the silicide layer 212 that is retained has a regular crystal orientation structure that can provide better protection to the optical device, including but not limited to: insulation, scratch resistance, prevention of overexposure to the external environment, and the like.

It is worth mentioning that the mechanical grinding has high efficiency but poor precision, while the chemical mechanical polishing and etching processes have low efficiency but high precision, so in this specific example, it is preferable to perform the first stage of treatment on the silicon base layer 211 by the mechanical grinding and polishing, and then perform the second stage of treatment on the silicon base layer 211 by the chemical mechanical polishing or etching process to remove the silicon base layer 211.

In other embodiments of this specific example, the process for manufacturing the optical device further includes: at least a portion of the silicide layer 212 is removed, i.e., the silicide layer 212 is further processed to thin the silicide layer 212.

In summary, the optical device and the manufacturing method thereof based on this specific example are illustrated, which migrate the silicide layer having the preferred crystal orientation arrangement to the surface of the optical device 300 to be transferred in a specific manufacturing method, so that the surface of the optical device finally manufactured has the optical layer structure having the preferred crystal orientation arrangement.

Specific example 3

Fig. 7 illustrates a schematic diagram of still another specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 7, in this specific example, the optical device is a spectrum chip, the optical device body 110 is a spectrum chip semi-finished product 400, and the purpose of the preparation method is to: a silicon crystal layer 513 with a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product 400, and the silicon crystal layer 513 has a light modulation structure 510 for modulating the imaging light entering the spectrum chip so as to extract and utilize the spectrum information in the imaging light.

Here, the spectroscopic chip to which the present application relates is applied to a computational spectrometer, wherein the most significant difference between a computational spectrometer and a conventional spectrometer is the difference in optical filtering. In a conventional spectrometer, the filters used for wavelength selection are bandpass filters. The higher the spectral resolution, the narrower and more filters must be used, which increases the overall system size and complexity. Meanwhile, when the spectral response curve is narrowed, the luminous flux is decreased, resulting in a decrease in the signal-to-noise ratio.

For a computational spectrometer, however, each filter uses a broad spectrum filter, which makes the data detected by the computational spectrometer system look totally different from the original spectrum. However, by applying a computational reconstruction algorithm, the original spectrum can be recovered by computation. Since the broadband filter passes more light than the narrowband filter, the spectrometer can detect spectra from darker scenes. Furthermore, according to the compressive sensing theory, the spectral curve of the filter can be properly designed to recover the sparse spectrum with high probability, and the number of filters is much smaller than the desired number of spectral channels (recovering higher-dimensional vectors from lower-dimensional vectors), which is undoubtedly very advantageous for miniaturization. On the other hand, by using a larger number of filters, a regularization algorithm (lower dimensional vectors after noise reduction are obtained from higher dimensional vectors) can be used to reduce noise, which increases the signal-to-noise ratio and makes the overall system more robust.

In contrast, when a conventional spectrometer is designed, a filter (the effect of which is equal to that of an optical modulation structure of a spectrum chip) needs to be designed according to a required wavelength, so that light with a specific wavelength can be transmitted (generally, the filter is designed to enhance the projection of incident light with the specific wavelength, but incident light with a non-specific wavelength band cannot be projected, the resonance condition can be controlled by changing the period and the diameter of a structure such as a nano disc, and the central wavelength of the incident light capable of enhancing the projection is changed, so that the filtering characteristic is realized). That is, the conventional spectrometer needs to control the size and position accuracy of the light modulation structure during the design process, and needs to improve the transmittance of a specific wavelength. For computational spectrometers, however, it is desirable to be able to receive light over a wide range of wavelength bands (e.g., 350nm to 900nm), and therefore, to focus more on the refractive index at the time of design.

Accordingly, as described above, in this example, the spectrum chip is manufactured in the manufacturing method, that is, the silicon crystal layer having a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product, and the silicon crystal layer has a light modulation structure and a relatively large refractive index, so that light of a relatively large range of wavelength bands can be collected and utilized.

In this particular example, the spectroscopic chip blank 400 includes an image sensing layer 410 and a signal processing circuit layer 420 connected to the image sensing layer 410. It is worth mentioning that the spectrum chip semi-finished product 400 may also include other structures, and more specifically, in this example, the semi-finished product of the spectrum chip without the silicon base layer 511 having the light modulation structure 501 may be referred to as the spectrum chip semi-finished product 400.

In this specific example, the spectrum chip semi-finished product 400 may be provided by a manufacturer, or may be obtained by processing an existing photosensitive chip. Those skilled in the art will appreciate that the conventional photo chip, such as a CCD photo chip, a CMOS photo chip, includes a microlens layer, a color filter layer (not including a color filter layer if a black and white chip is used), an image sensing layer 410, and a signal processing circuit layer 420. Accordingly, the spectrum chip semi-finished product 400 can be obtained by removing the microlens layer and the color filter layer of the existing photosensitive chip (if the chip is a black-and-white chip, only the microlens layer needs to be removed). That is, by applying the manufacturing method of the optical device according to the embodiment of the present application, the spectrum chip applied to the computing spectrometer can be manufactured using the existing photosensitive chip, thereby reducing the application cost.

As shown in fig. 7, in this specific example, the optical device manufacturing process includes first pre-treating the surface of the spectrum chip semi-finished product 400 to form a flat bonding surface on the surface of the spectrum chip semi-finished product 400 for bonding the transfer member 200 with the target transfer layer 510.

Specifically, in this specific example, the process of preprocessing the surface of the spectrum chip semi-finished product 400 includes: a light-permeable medium layer 430 is formed on the surface of the spectrum chip semi-finished product 400, wherein the light-permeable medium layer 430 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the spectrum chip semi-finished product 400.

It is worth mentioning that in the implementation, although the light-permeable medium layer 430 needs a relatively high refractive index, the refractive index of the light-permeable medium layer 430 is not too high, because: it is necessary to ensure a difference in refractive index between the light-permeable medium layer 430 and the semiconductor structure layer located thereon.

In this specific example, the light-permeable medium layer 430 is preferably made of silicide, such as silicon dioxide, silicon nitride, etc. Those skilled in the art will appreciate that silicon dioxide has a refractive index of about 1.45 and silicon nitride has a refractive index of between 1.9 and 2.3.

In a specific implementation, the light-permeable medium layer 430 may be formed on the surface of the spectrum chip semi-finished product 400 by a non-metal vapor deposition process, for example, but in other embodiments of this specific implementation, the light-permeable medium layer 430 may also be formed by other processes, and the formation process is not limited in this application. In particular, in this specific example, the thickness of the light-permeable medium layer 430 is not limited in this application, and the specific value thereof can be adjusted according to the specific requirements of the application scenario, and in general, the thickness is less than or equal to 300nm, and in some special scenarios, it is even less than 100nm,

as shown in fig. 5, in this specific example, the upper surface of the light-permeable medium layer 430 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 430 for combining with the transfer member 200 has a relatively high flatness, so as to facilitate the transfer member 200 to the spectrum chip semi-finished product 400.

It is worth mentioning that in some cases of this specific example, the surface of the spectrum chip semi-finished product 400 may be non-flat, and the upper surface of the light-permeable medium layer 430 formed on the surface of the spectrum chip semi-finished product 400 by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the spectrum chip semi-finished product 400, and/or polishing and grinding the upper surface of the light-permeable medium layer 430. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

It is worth mentioning that, in this specific example, if the surface flatness of the spectrum chip semi-finished product 400 meets the preset requirement, the light-permeable medium layer 430 may not be disposed on the surface of the spectrum chip semi-finished product 400, that is, the spectrum chip semi-finished product 400 does not need to be pretreated.

Further, as shown in fig. 7, the process of manufacturing the optical device further includes: a transfer member 500 is provided. In particular, in this specific example, the transfer member 500 is selected as an SOI device (Silicon on insulator, Silicon device) which includes, in order from bottom to top: a silicon base layer 511, a silicide layer 512 and a silicon crystal layer 513, wherein the silicon crystal layer 513 is a target transfer layer 510 of the transfer member 500 to be transferred, that is, in this specific example, the target transfer layer 510 of the transfer member 500 is located at the uppermost layer of the transfer member 500. It will be appreciated by those skilled in the art that the SOI device is an existing device, and the existing device including the target transition layer 510 is used as the transition member 500, so that the cost can be reduced on the one hand, and the existing device has developed the technology and has stable and predictable performance.

Also, as one of ordinary skill in the art would know, in the SOI device, the arrangement of atoms in the silicon base layer 511, the silicide layer 512 and the silicon crystal layer 513 is regular, i.e., all three have a good crystal orientation structure. Preferably, in this particular example, the surface of the silicon crystal layer 513 is a flat surface.

As shown in fig. 7, the process of manufacturing the optical device further includes: the transfer member 500 is coupled to the spectrum chip semi-finished product 400 in such a manner that the upper surface of the transfer member 500 is bonded to the upper surface of the light-permeable medium layer 430 of the spectrum chip semi-finished product 400. That is, the SOI device is migrated to the spectroscopic chip semi-finished product 400 in such a manner that the surface of the silicon crystal layer 513 of the SOI device is bonded to the upper surface of the light-permeable medium layer 430 of the spectroscopic chip semi-finished product 400.

In order to ensure the bonding strength between the transfer member 500 and the spectrum chip semi-finished product 400, preferably, in the embodiment of the present application, the upper surface of the transfer member 500 and the upper surface of the light-permeable medium layer 430 have a good bonding reaction, so that the two surfaces can generate a good bonding reaction during bonding, and generate a larger bonding force. For example, in this particular example, the upper surface of the transfer member 500 is configured to be made of the same material as the light-permeable medium layer 430, so that the two can generate a good bonding reaction and generate a larger bonding force when bonding.

Taking the light-permeable medium layer 430 as an example of silicon dioxide, it should be understood that in this particular example, the upper surface of the transfer member 500 is formed by the surface of the silicon crystal layer 513. Thus, in this implementation, before bonding the upper surface of the transfer member 500 to the upper surface of the light-permeable medium layer 430, further comprises: the upper surface of the transfer member 500 is treated so that the upper surface of the transfer member 500 is made of a silicon oxide material.

In a specific implementation, oxygen ions may be implanted into the surface of the silicon crystal layer 513 to form a silicon dioxide layer on the surface portion of the silicon crystal layer 513, so that the upper surface of the transfer 500 is formed of silicon dioxide. It should be understood that the silicon crystal layer 513 has a regular crystal orientation structure, and therefore, the silicon dioxide layer also has a regular crystal orientation structure, so as to facilitate the bonding effect with the light-permeable medium layer 430.

Of course, in other embodiments of this specific example, a bonding layer 520 may also be stacked on the surface of the silicon crystal layer 513, wherein the bonding layer 520 is made of a silicon dioxide material, and the bonding layer 520 is formed by, for example, a non-metal vapor deposition process to be stacked on the surface of the silicon crystal layer 513, so as to improve the bonding strength between the transfer member 500 and the spectrum chip semi-finished product 400 by the bonding layer 520.

It should be noted that, in this specific example, the process of processing the upper surface of the transfer member 500 may also be completed in the step of providing the transfer member 500, and this is not a limitation of the present application.

As shown in fig. 7, the process of manufacturing the optical device further includes: the target transfer layer 510 of the transfer member 500 is left, that is, the silicon crystal layer 513 of the transfer member 500 is left. In this particular example, the silicon base layer 511 and the silicide layer 512 may be removed using one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes such that the silicon crystal layer 513 of the transfer 500 is retained.

It is worth mentioning that the mechanical grinding has high efficiency but poor precision, while the chemical mechanical polishing and etching processes have low efficiency but high precision, so in this specific example, it is preferable to perform the first stage of treatment on the silicon base layer 511 and the silicide layer 512 by mechanical grinding and polishing, and then perform the second stage of treatment on the silicon base layer 511 and the silicide layer 512 by chemical mechanical polishing or etching processes to achieve both efficiency and precision.

In particular, in the embodiment of the present application, the refractive index of the silicon crystal layer 513 is about 3.42, and the difference between the refractive indices of the silicon crystal layer 513 and the light-permeable medium layer 430 is equal to or greater than 0.5, preferably equal to or greater than 0.7.

In particular, in this particular example, the spectroscopic chip has certain requirements on the thickness of the silicon crystal layer 513, and the silicon crystal layer 513 has a thickness dimension in the range of 5nm to 1000nm, preferably 50nm to 750nm, which facilitates the processing of the silicon substrate layer 511 by thickness, so that the imaging effect of the spectroscopic chip is optimized and ensured. More preferably, the thickness dimension of the silicon crystal layer 513 is between 150nm and 250 nm.

Accordingly, in this specific example, in order to meet the thickness requirement, in the process of removing the silicon base layer 511 and the silicide layer 512, a part of the silicon crystal layer 513 is further removed, so that the thickness dimension of the silicon crystal layer 513 meets the preset requirement.

As shown in fig. 7, the process of manufacturing the optical device further includes: forming a light modulation structure 501 on the remaining silicon crystal layer 513 so that the silicon crystal layer 513 has the light modulation structure 501, so that when external imaging light enters the inside of the spectrum chip through the silicon crystal layer 513, the silicon crystal layer 513 having the light modulation structure 501 can modulate the imaging light to extract and utilize spectrum information in the imaging light. It will be appreciated by those skilled in the art that the light modulation structure 501 is essentially a specific pattern formed in the silicon crystal layer 513 to perform a specific modulation process on the imaging light through the specific pattern.

In particular, in this particular example, the refractive index of the light modulating structure 501 is between 1 and 5, and the difference between the refractive index of the light modulating structure 501 and the refractive index of the light permeable medium layer 430 is greater than or equal to 0.5, preferably greater than or equal to 0.7, so that light of a relatively large range of wavelengths can pass through the light permeable medium layer 430 and the image sensing layer 410 of the spectral chip after passing through the light modulating structure 501.

In this particular example implementation, the light modulating structure 501 may be formed on the silicon crystal layer 513 by an etching process, a nanoimprinting process, or the like. The specific process flow of the nano silk-screen printing process is as follows: firstly, coating a photosensitive material (such as photoresist) on the surface of a metal film on a wafer; then, a template having a filter pattern engraved thereon is pressed, and particularly, the template is transparent; then, ultraviolet light (UV light) is irradiated thereto to harden the photoresist on which the template pattern has been printed. The patterned photoresist is then visible by stripping the template. Accordingly, after the light modulation structure 501 is formed, the spectrum chip is prepared.

It should be appreciated that in this particular example, the atoms in the silicon crystal layer 513 of the transfer member 500 have a regular distribution of crystal orientations, and the internal structure of the silicon crystal layer 513 is not altered when transferred to the surface of the spectroscopic chip blank 400 by the fabrication method described above. Therefore, the spectrum chip manufactured by the manufacturing method disclosed in this embodiment has an optical layer structure with a better crystal orientation arrangement formed on the surface thereof.

In summary, the spectroscopic chip and the manufacturing method thereof based on this specific example are illustrated, which migrate the silicon crystal layer 513 with a preferred crystal orientation arrangement to the surface of the spectroscopic chip semi-finished product 400 in a specific manufacturing method, so that the surface of the spectroscopic chip finally manufactured has an optical layer structure with a preferred crystal orientation arrangement.

Fig. 8 illustrates a schematic diagram of a variant implementation of the specific example illustrated in fig. 7. As shown in fig. 8, in this variant implementation, a portion of the silicide layer 512 in the transfer member 500 is left, that is, in this variant implementation, only the silicon base layer 511 and at least a portion of the silicide layer 512 are removed, so that a portion of the silicide layer 512 and the silicon crystal layer 513 is left. Here, the silicide layer 512 that is left can provide a certain protection effect to the silicon crystal layer 513. Accordingly, during subsequent formation of the light modulating structure 501, the remaining silicide layer 512 is also partially etched, as shown in fig. 8.

In particular, in this variant implementation, the silicide layer 512 has a regular crystal orientation structure, which does not affect the transmittance, while the silicide layer 512 may also protect the light modulating structure 501; it is worth mentioning that the maximum distance from the upper surface of the silicide layer 512 to the upper surface of the light-permeable medium layer 430 is not more than 1100nm, preferably not more than 700 nm.

Fig. 9 illustrates a schematic diagram of another variant implementation of the specific example illustrated in fig. 7. As shown in fig. 9, in the preparation method disclosed in this modified embodiment, before the transfer 500 is transferred to the spectrum chip semi-finished product 400 through the bonding process, the silicon crystal layer 513 of the transfer 500 is pretreated to form the light modulation structure 501 in the silicon crystal layer 513, wherein the thickness of the silicon crystal layer 513 is 200-1000nm, preferably 350-600 nm. Accordingly, when the silicon crystal layer 513 is subsequently retained, the light modulation structure 501 of the silicon crystal layer 513 is also retained simultaneously.

That is, in this modified embodiment, compared to the manufacturing scheme illustrated in fig. 7, the light modulation structure 501 is prefabricated on the transfer member 500, or the process of forming the light modulation structure 501 is adjusted forward.

Specific example 4

Fig. 10 illustrates a schematic diagram of yet another specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 10, in this specific example, the optical device is a spectrum chip, the optical device body 110 is a spectrum chip semi-finished product 400, and the purpose of the preparation method is to: a silicon crystal layer 511 with a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product 400, and the silicon crystal layer 511 is provided with a light modulation structure 501 for modulating the imaging light entering the spectrum chip so as to extract and utilize the spectrum information in the imaging light.

Here, the spectroscopic chip to which the present application relates is applied to a computational spectrometer, wherein the most significant difference between a computational spectrometer and a conventional spectrometer is the difference in optical filtering. In a conventional spectrometer, the filters used for wavelength selection are bandpass filters. The higher the spectral resolution, the narrower and more filters of the passband must be used, which increases the bulk and complexity of the overall system. Meanwhile, when the spectral response curve is narrowed, the luminous flux is decreased, resulting in a decrease in the signal-to-noise ratio.

For a computational spectrometer, however, a broad spectrum filter is used for each filter, which makes the data detected by the computational spectrometer system look completely different from the original spectrum. However, by applying a computational reconstruction algorithm, the original spectrum can be recovered by computation. Since the broadband filter passes more light than the narrowband filter, the spectrometer can detect spectra from darker scenes. Furthermore, according to the compressive sensing theory, the spectral curve of the filter can be properly designed to recover the sparse spectrum with high probability, and the number of filters is much smaller than the desired number of spectral channels (recovering higher-dimensional vectors from lower-dimensional vectors), which is undoubtedly very advantageous for miniaturization. On the other hand, by using a larger number of filters, a regularization algorithm (lower dimensional vectors after noise reduction are obtained from higher dimensional vectors) can be used to reduce noise, which increases the signal-to-noise ratio and makes the overall system more robust.

In contrast, when a conventional spectrometer is designed, a filter (the effect of which is equal to that of an optical modulation structure of a spectrum chip) needs to be designed according to a required wavelength, so that light with a specific wavelength can be transmitted (generally, the filter is designed to enhance the projection of incident light with the specific wavelength, but incident light with a non-specific wavelength band cannot be projected, the resonance condition can be controlled by changing the period and the diameter of a structure such as a nano disc, and the central wavelength of the incident light capable of enhancing the projection is changed, so that the filtering characteristic is realized). That is, the conventional spectrometer needs to control the size and position accuracy of the light modulation structure during the design process, and needs to improve the transmittance of a specific wavelength. For computational spectrometers, however, it is desirable to be able to receive light over a wide range of wavelength bands (e.g., 350nm to 900nm), and therefore, to focus more on the refractive index at the time of design.

Accordingly, as described above, in this example, the spectrum chip is manufactured in the manufacturing method, that is, the silicon crystal layer 511 having a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product 400, and the silicon crystal layer 511 has the light modulation structure 501 and has a relatively large refractive index, so that light of a relatively large range of wavelength bands can be collected and utilized.

In this particular example, the spectroscopic chip blank 400 includes an image sensing layer 410 and a signal processing circuit layer 420 connected to the image sensing layer 410. It is worth mentioning that the spectrum chip semi-finished product 400 may also include other structures, and more specifically, in this example, the spectrum chip semi-finished product in which the silicon crystal layer 511 with the light modulation structure 501 is not formed may be referred to as the spectrum chip semi-finished product 400.

In this specific example, the spectrum chip semi-finished product 400 may be provided by a manufacturer, or may be obtained by processing an existing photosensitive chip. Those skilled in the art will appreciate that the conventional photo chip, such as a CCD photo chip, a CMOS photo chip, includes a microlens layer, a color filter layer (not including a color filter layer if a black and white chip is used), an image sensing layer 410, and a signal processing circuit layer 420. Accordingly, the spectrum chip semi-finished product 400 can be obtained by removing the microlens layer and the color filter layer of the existing photosensitive chip (if the chip is a black-and-white chip, only the microlens layer needs to be removed). That is, by applying the manufacturing method of the optical device according to the embodiment of the present application, the spectrum chip applied to the computing spectrometer can be manufactured using the existing photosensitive chip, thereby reducing the application cost.

As shown in fig. 10, in this specific example, the preparation process of the optical device includes first pre-treating the surface of the spectrum chip semi-finished product 400 to form a flat bonding surface for bonding the transfer member 500 with the target transfer layer 510 on the surface of the spectrum chip semi-finished product 400.

Specifically, in this specific example, the process of preprocessing the surface of the spectrum chip semi-finished product 400 includes: a light-permeable medium layer 430 is formed on the surface of the spectrum chip semi-finished product 400, wherein the light-permeable medium layer 430 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the spectrum chip semi-finished product 400.

It is worth mentioning that in the implementation, although the light-permeable medium layer 430 needs a relatively high refractive index, the refractive index of the light-permeable medium layer 430 is not too high, because: it is necessary to ensure a difference in refractive index between the light-permeable medium layer 430 and the semiconductor structure layer located thereon.

In this specific example, the light-permeable medium layer 430 is preferably made of silicide, such as silicon dioxide, silicon nitride, etc. Those skilled in the art will appreciate that silicon dioxide has a refractive index of about 1.45 and silicon nitride has a refractive index of between 1.9 and 2.3.

In a specific implementation, the light-permeable medium layer 430 may be formed on the surface of the spectrum chip semi-finished product 400 by a non-metal vapor deposition process, for example, but in other embodiments of this specific implementation, the light-permeable medium layer 430 may also be formed by other processes, and the formation process is not limited in this application. In particular, in this specific example, the thickness of the light-permeable medium layer 430 is not limited in this application, and the specific value thereof can be adjusted according to the specific requirements of the application scenario, and in general, the thickness is less than or equal to 300nm, and in some special scenarios, the thickness is even less than 100 nm.

As shown in fig. 10, in this specific example, the upper surface of the light-permeable medium layer 430 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 430 for combining with the transfer member 500 has a relatively high flatness, so as to facilitate the transfer member 500 to the spectrum chip semi-finished product 400.

It is worth mentioning that in some cases of this specific example, the surface of the spectrum chip semi-finished product 400 may be non-flat, and the upper surface of the light-permeable medium layer 430 formed on the surface of the spectrum chip semi-finished product 400 by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the spectrum chip semi-finished product 400, and/or polishing and grinding the upper surface of the light-permeable medium layer 430. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

It is worth mentioning that, in this specific example, if the surface flatness of the spectrum chip semi-finished product 400 meets the preset requirement, the light-permeable medium layer 430 may not be disposed on the surface of the spectrum chip semi-finished product 400, that is, the spectrum chip semi-finished product 400 does not need to be pretreated.

Further, as shown in fig. 10, the process of manufacturing the optical device further includes: a transfer member 500 is provided. In particular, in this particular example, the transfer member 500 is a homemade semiconductor device, which in turn comprises: a silicon crystal layer 511 and a silicide layer 512 formed under the silicon base layer 511, wherein the silicon crystal layer 511 is a target transfer layer 510 of the to-be-transferred article 500, that is, in this specific example, the target transfer layer 510 of the to-be-transferred article 500 is located at an upper layer of the to-be-transferred article 500.

In particular, in the present embodiment, the crystal orientation arrangement of atoms in the silicon crystal layer 511 (i.e., the target transfer layer 510) is regular. In this specific example, the refractive index of the silicon crystal layer 511 is about 3.42, and the difference in refractive index between the silicon crystal layer 511 and the light-permeable medium layer 430 is 0.5 or more, preferably 0.7 or more.

In one implementation of this particular example, the homemade transfer member 500 may be prepared as follows: firstly, forming a monocrystalline silicon structure with a regular crystal orientation structure by a Czochralski method, a suspension zone melting method or other processes; further, a portion of the single-crystal silicon structure is processed to obtain the silicide layer 512, wherein the unprocessed portion of the single-crystal silicon structure forms the silicon crystal layer 511, for example, when the silicide layer 512 is a silicon dioxide layer, oxygen ions may be implanted at a corresponding position of the single-crystal silicon structure to form the silicon dioxide layer. It should be understood that because the atoms within the single crystal silicon structure have a regular distribution of crystal orientations, the silicon crystal layer 511 also has a regular structure of crystal orientations. Preferably, in this specific example, the surface of the silicon crystal layer 511 is a flat surface.

Further, it will be understood by those skilled in the art that the transfer member 500 may also be a semiconductor device obtained directly by purchase or customization so that the semiconductor device can be bonded directly to the upper surface of the light-permeable medium layer 630 without further processing.

That is, unlike the specific example 3, in the specific example 4, the transfer 500 may include only the silicon crystal layer 511 and the silicide layer 512, wherein the silicon crystal layer 511 serves as the target transfer layer 510 of the to-be-transferred 500, and the silicide layer 512 serves as a bonding layer that helps the silicon base layer 511 bond to the upper surface of the light-permeable medium layer 430. In this way, the silicide layer 512 can function similarly to the bonding layer 520 in specific example 3, or can be said to be equivalent to the bonding layer 520 in specific example 3, thereby improving the bonding strength between the silicon crystal layer 511 and the spectrum chip semi-finished product 400. Here, since the silicide layer 512 is based between the silicon crystal layer 511 and the spectroscopic chip half-product 400, its thickness is less than 600nm, preferably 300-400nm, and can also be implemented to be less than 200nm, so as not to affect the optical performance.

As shown in fig. 10, the process of manufacturing the optical device further includes: the transfer member 500 is coupled to the spectrum chip semi-finished product 400 in such a way that the lower surface of the transfer member 500 is bonded to the upper surface of the light-permeable medium layer 430 of the spectrum chip semi-finished product 400, so as to form a spectrum chip with light modulation decoupling. That is, the transfer member 500 is transferred to the spectroscopic chip semi-finished product 400 in such a manner that the surface of the silicide layer 512 of the transfer member 500 is bonded to the upper surface of the light-permeable medium layer 430 of the spectroscopic chip semi-finished product 400. Also, since the transfer member 500 in the specific example includes only the silicon crystal layer 511 and the silicide layer 512, a spectrum chip having light modulation decoupling can be directly formed.

In order to ensure the bonding strength between the transferring member 500 and the spectrum chip semi-finished product 400, in the embodiment of the present application, the lower surface of the transferring member 500 is a silicide layer 512, which has a good bonding reaction with the upper surface of the light-permeable medium layer 430, so that the two surfaces can generate a good bonding reaction during bonding, and generate a greater bonding force. For example, in this specific example, the silicide layer 512 is configured to have the same material as the light-permeable medium layer 430, so that the two can generate a good bonding reaction and generate a larger bonding force when bonding.

Taking the light-permeable dielectric layer 430 as an example of silicon dioxide, it should be understood that in this particular example, the lower surface of the transfer member 500 is formed by the surface of the silicide layer 512. Thus, in this implementation, the silicide layer 512 may be made of a silicon dioxide material. Moreover, it should be understood that the silicon crystal layer 511 has a regular crystal orientation structure, and therefore, the silicide layer 512 of silicon dioxide material also has a regular crystal orientation structure, so as to facilitate the bonding effect with the light-permeable medium layer 430.

In addition, it will be understood by those skilled in the art that in this particular example, the transfer 500 may include other layers, such as another silicide layer and/or a silicon substrate layer on the other side of the silicon crystal layer 511 opposite the silicide layer 512, in addition to the silicon crystal layer 511 and the silicide layer 512 described above.

Thus, the process of making the optical device optionally further comprises: the other layers are removed to leave the target transfer layer 510 of the transfer 500, that is, the silicon crystal layer 511 of the transfer 500. In this particular example, one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes may be used to remove 5 other layers so that the silicon crystal layer 511 of the transfer 500 remains.

It is worth mentioning that mechanical lapping is efficient but less accurate, while chemical mechanical polishing and etching processes are inefficient but more accurate, so in this particular example, it is preferable to perform a first stage of treatment on the other layer using mechanical lapping and polishing, followed by a second stage of treatment on the other layer using chemical mechanical polishing or etching processes to achieve both efficiency and accuracy.

In particular, in this specific example, the spectroscopic chip has certain requirements on the thickness of the silicon crystal layer 511, and the silicon crystal layer 511 has a thickness dimension in the range of 5nm to 1000nm, preferably 50nm to 750nm, which facilitates the processing of the silicon crystal layer 511 by thickness, so that the imaging effect of the spectroscopic chip is optimized and ensured. More preferably, the thickness dimension of the silicon crystal layer 511 is between 150nm and 250 nm.

Accordingly, in this specific example, in order to meet the thickness requirement, in the process of removing other layers, it is further included to remove a portion of the silicon crystal layer 511 so that the thickness dimension of the silicon crystal layer 511 meets a preset requirement.

As shown in fig. 10, the process of manufacturing the optical device further includes: forming a light modulation structure 501 on the remaining silicon crystal layer 511, so that the silicon crystal layer 511 is provided with the light modulation structure 501, so that when external imaging light enters the inside of the spectrum chip through the silicon crystal layer 511, the silicon crystal layer 511 provided with the light modulation structure 501 can modulate the imaging light to extract and utilize spectrum information in the imaging light. It will be appreciated by those skilled in the art that the light modulation structure 501 is essentially a specific pattern formed in the silicon crystal layer 511 to perform a specific modulation process on the image light through the specific pattern.

In particular, in this particular example, the refractive index of the light modulating structure 501 is between 1 and 5, and the difference between the refractive index of the light modulating structure 501 and the refractive index of the light permeable medium layer 430 is greater than or equal to 0.5, preferably greater than or equal to 0.7, so that light of a relatively large range of wavelengths can pass through the light permeable medium layer 430 and the image sensing layer 410 of the spectral chip after passing through the light modulating structure 501.

In this particular example implementation, the light modulating structure 501 may be formed on the silicon crystal layer 511 by an etching process, a nanoimprinting process, or the like. Accordingly, after the light modulation structure 501 is formed, the spectrum chip is prepared. The specific process flow of the nano silk-screen printing process is as follows: firstly, coating a photosensitive material (such as photoresist) on the surface of a metal film on a wafer; then, a template having a filter pattern engraved thereon is pressed, and particularly, the template is transparent; then, ultraviolet light (UV light) is irradiated thereto to harden the photoresist on which the template pattern has been printed. The patterned photoresist is then visible by stripping the template.

It should be understood that in this particular example, the atoms in the silicon crystal layer 511 of the transfer member 500 have a regular crystal orientation distribution, and the internal structure of the silicon crystal layer 511 is not changed when being transferred to the surface of the spectrum chip semi-finished product 400 by the preparation method as described above. Therefore, the spectral chip manufactured by the manufacturing method disclosed in this embodiment has an optical layer structure with a better crystal orientation arrangement formed on the surface thereof.

In summary, the spectroscopic chip and the manufacturing method thereof based on this specific example are illustrated, which migrate the silicon crystal layer 511 with a preferred crystal orientation arrangement to the surface of the spectroscopic chip semi-finished product 400 in a specific manufacturing method, so that the surface of the spectroscopic chip finally manufactured has an optical layer structure with a preferred crystal orientation arrangement.

It is worth mentioning that in some variant implementations of this particular example, if the transfer member 500 further comprises other layers on the other side of the silicon crystal layer 511 opposite to the silicide layer 512, such as another silicide layer and/or a silicon substrate layer, a portion of the other layers may also be retained, i.e. in this variant implementation, only at least a portion of the other layers is removed, so that a portion of the other layers and the silicon crystal layer 511 are retained, such as the other layer of the silicide layer 512 shown in fig. 11. Here, the part of the other layers that is left can provide a certain protection effect to the silicon crystal layer 511. Accordingly, during subsequent formation of the light modulating structure 501, the remaining portions of the other layers, such as the additional silicide layer 512 shown in FIG. 11, are also partially etched, which has the final shaping effect shown in FIG. 11. In particular, in this variant implementation, said part of the other layers also has a regular crystallographic orientation structure, which does not affect the transmittance, while said part of the other layers may also protect said light modulating structure 501; it is worth mentioning that the maximum distance from the upper surface of said part of the other layer to the upper surface of said light-permeable medium layer 430 is not more than 1100nm, preferably not more than 700 nm.

It is further worth mentioning that in further variants of this particular example, the silicon crystal layer 511 of the transfer piece 500 is pre-treated to form the light modulating structure 501 within the silicon crystal layer 511 before the transfer piece 500 is transferred to the spectroscopic chip semi-finished product 400 by a bonding process, wherein the silicon crystal layer has a thickness of 200-. Accordingly, when the silicon crystal layer 511 is subsequently retained, the light modulation structure 501 of the silicon crystal layer 511 is also retained synchronously. That is, in this modified embodiment, the light modulation structure 501 is previously prepared on the transfer member 500, or the process of forming the light modulation structure 501 is adjusted forward.

Those skilled in the art will understand that in another modified embodiment, the lower surface of the silicon crystal layer 511 may be bonded to the light-permeable medium layer 430, and then the silicide layer 512 and a portion of the silicon crystal layer 511 are removed, or a portion of the silicide layer 512 is removed; the specific process is closer to that of the specific example 3, except that the transfer member 500 is different.

In addition, there is a modified embodiment, in which the to-be-transferred member 500 only includes a silicide layer, that is, the target transfer layer 510 of the to-be-transferred member 500 is the silicide layer 512, and the silicide layer 512 also forms the light modulation structure, for example, the light modulation structure is fabricated after being transferred to the light-permeable medium layer 430 or is prefabricated before being transferred to the light-permeable medium layer 430, and the specific process is similar to that of the specific example 4, and will not be described again here.

Specific example 5

Fig. 12 illustrates a schematic diagram of yet another specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 12, in this specific example, the optical device is a spectrum chip, the optical device body 110 is a spectrum chip semi-finished product 400, and the purpose of the preparation method is to: a silicon substrate layer 511 with a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product 400, and the silicon substrate layer 511 is provided with a light modulation structure 501 for modulating the imaging light entering the spectrum chip so as to extract and utilize the spectrum information in the imaging light.

Here, the spectroscopic chip to which the present application relates is applied to a computational spectrometer, wherein the most significant difference between a computational spectrometer and a conventional spectrometer is the difference in optical filtering. In a conventional spectrometer, the filters used for wavelength selection are bandpass filters. The higher the spectral resolution, the narrower and more filters of the passband must be used, which increases the bulk and complexity of the overall system. Meanwhile, when the spectral response curve is narrowed, the luminous flux is decreased, resulting in a decrease in the signal-to-noise ratio.

For a computational spectrometer, however, a broad spectrum filter is used for each filter, which makes the data detected by the computational spectrometer system look completely different from the original spectrum. However, by applying a computational reconstruction algorithm, the original spectrum can be recovered by computation. Since the broadband filter passes more light than the narrowband filter, the spectrometer can detect spectra from darker scenes. Furthermore, according to the compressive sensing theory, the spectral curve of the filter can be properly designed to recover the sparse spectrum with high probability, and the number of filters is much smaller than the desired number of spectral channels (recovering higher-dimensional vectors from lower-dimensional vectors), which is undoubtedly very advantageous for miniaturization. On the other hand, by using a larger number of filters, a regularization algorithm (lower dimensional vectors after noise reduction are obtained from higher dimensional vectors) can be used to reduce noise, which increases the signal-to-noise ratio and makes the overall system more robust.

In contrast, when a conventional spectrometer is designed, a filter (the effect of which is equal to that of an optical modulation structure of a spectrum chip) needs to be designed according to a required wavelength, so that light with a specific wavelength can be transmitted (generally, the filter is designed to enhance the projection of incident light with the specific wavelength, but incident light with a non-specific wavelength band cannot be projected, the resonance condition can be controlled by changing the period and the diameter of a structure such as a nano disc, and the central wavelength of the incident light capable of enhancing the projection is changed, so that the filtering characteristic is realized). That is, the conventional spectrometer needs to control the size and position accuracy of the light modulation structure during the design process, and needs to improve the transmittance of a specific wavelength. For computational spectrometers, however, it is desirable to be able to receive light over a wide range of wavelength bands (e.g., 350nm to 900nm), and therefore, to focus more on the refractive index at the time of design.

Accordingly, as described above, in this example, the spectrum chip is manufactured in a specific manufacturing method, that is, the silicon substrate layer 511 having a regular crystal orientation structure is formed on the surface of the spectrum chip semi-finished product 400, and the silicon substrate layer 511 has the light modulation structure 501 and has a relatively large refractive index, so that light of a relatively large range of wavelength bands can be collected and utilized.

In this particular example, the spectroscopic chip blank 400 includes an image sensing layer 410 and a signal processing circuit layer 420 connected to the image sensing layer 410. It is worth mentioning that the spectrum chip semi-finished product 400 may also include other structures, and more specifically, in this example, the semi-finished product of the spectrum chip without the silicon base layer 511 having the light modulation structure 501 may be referred to as the spectrum chip semi-finished product 400.

In this specific example, the spectrum chip semi-finished product 400 may be provided by a manufacturer, or may be obtained by processing an existing photosensitive chip. Those skilled in the art will appreciate that the conventional photo chip, such as a CCD photo chip, a CMOS photo chip, includes a microlens layer, a color filter layer (here, if a black and white chip, the color filter layer is not included), an image sensing layer 410 and a signal processing circuit layer 420. Accordingly, the spectrum chip semi-finished product 400 can be obtained by removing the microlens layer and the color filter layer of the existing photosensitive chip (if the chip is a black-and-white chip, only the microlens layer needs to be removed). That is, by applying the manufacturing method of the optical device according to the embodiment of the present application, the spectrum chip applied to the computing spectrometer can be manufactured using the existing photosensitive chip, thereby reducing the application cost.

As shown in fig. 12, in this specific example, the optical device manufacturing process includes first pre-treating the surface of the spectrum chip semi-finished product 400 to form a flat bonding surface on the surface of the spectrum chip semi-finished product 400 for bonding the transfer member 500 with the target transfer layer 510.

Specifically, in this specific example, the process of preprocessing the surface of the spectrum chip semi-finished product 400 includes: a light-permeable medium layer 430 is formed on the surface of the spectrum chip semi-finished product 400, wherein the light-permeable medium layer 430 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the spectrum chip semi-finished product 400.

It is worth mentioning that in the implementation, although the light-permeable medium layer 430 needs a relatively high refractive index, the refractive index of the light-permeable medium layer 430 is not too high, because: it is desirable to ensure a difference in refractive index between the light-permeable medium layer 430 and the semiconductor structures located thereon.

In this specific example, the light-permeable medium layer 430 is preferably made of silicide, such as silicon dioxide, silicon nitride, etc. Those skilled in the art will recognize that silicon dioxide has a refractive index of about 1.45 and silicon nitride has a refractive index of between about 1.9 and 2.3.

In a specific implementation, the light-permeable medium layer 430 may be formed on the surface of the spectrum chip semi-finished product 400 by a non-metal vapor deposition process, for example, but the light-permeable medium layer 430 may also be formed by other processes in other embodiments of the specific implementation, and the application is not limited thereto. In particular, in this specific example, the thickness of the light-permeable medium layer 430 is not limited in this application, and the specific value thereof can be adjusted according to the specific requirements of the application scenario, and in general, the thickness is less than or equal to 300nm, and in some special scenarios, it is even less than 100nm,

as shown in fig. 12, in this specific example, the upper surface of the light-permeable medium layer 430 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 430 for combining with the transfer member 500 has a relatively high flatness, so as to facilitate the transfer member 500 to the spectrum chip semi-finished product 400.

It is worth mentioning that in some cases of this specific example, the surface of the spectrum chip semi-finished product 400 may be non-flat, and the upper surface of the light-permeable medium layer 430 formed on the surface of the spectrum chip semi-finished product 400 by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the spectrum chip semi-finished product 400, and/or polishing and grinding the upper surface of the light-permeable medium layer 430. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

It is worth mentioning that, in this specific example, if the surface flatness of the spectrum chip semi-finished product 400 meets the preset requirement, the light-permeable medium layer 430 may not be disposed on the surface of the spectrum chip semi-finished product 400, that is, the spectrum chip semi-finished product 400 does not need to be pretreated.

Further, as shown in fig. 12, the process of manufacturing the optical device further includes: a transfer member 500 is provided. In particular, in this particular example, the transfer 500 is a silicon substrate layer 511, that is, in this particular example, the transfer 500 includes only the target transfer layer 510, and the target transfer layer 510 is the silicon substrate layer 511. In particular, in the present embodiment, the crystal orientation arrangement of atoms in the silicon substrate layer 511 (i.e., the target transfer layer 510) is regular. The refractive index of the silicon base layer 511 is about 3.42, and the difference in refractive index between the silicon base layer 511 and the light-permeable medium layer 430 is 0.5 or more, preferably 0.7 or more.

In one implementation of this particular example, the homemade transfer member 500 may be prepared as follows: first, a single crystal silicon structure having a regular crystal orientation structure is formed by a process such as a czochralski method or a floating zone method, wherein the single crystal silicon structure is the silicon base layer 511, that is, the single crystal silicon structure is the transfer 500. It should be understood that because the atoms within the single crystal silicon structure have a regular distribution of crystal orientations, the silicon base layer 511 also has a regular structure of crystal orientations. Preferably, in this specific example, the surface of the silicon base layer 511 is a flat surface.

It is noted that in this specific example, the transfer member 500 may also include only the silicon base layer 511, i.e., without the silicide layer 512, and this is not a limitation of this example.

As shown in fig. 12, the process of manufacturing the optical device further includes: the transfer member 500 is coupled to the spectrum chip semi-finished product 400 in such a manner that the lower surface of the transfer member 500 is bonded to the upper surface of the light-permeable medium layer 430 of the spectrum chip semi-finished product 400. That is, the transfer member 500 is transferred to the spectrum chip semi-finished product 400 in such a manner that the surface of the silicon base layer 511 (here, the upper surface of the silicon base layer 511, or the lower surface of the silicon base layer 511) is bonded to the upper surface of the light-permeable medium layer 430 of the spectrum chip semi-finished product 400.

In order to ensure the bonding strength between the transfer member 500 and the spectrum chip semi-finished product 400, preferably, in the embodiment of the present application, the upper surface or the lower surface of the transfer member 500 and the upper surface of the light-permeable medium layer 430 have a good bonding reaction, so that the two surfaces can generate a good bonding reaction during bonding, and generate a larger bonding force. For example, in this specific example, the lower surface of the silicon base layer 511 or the upper surface of the silicon base layer 511 is configured to have the same material as that of the light-permeable medium layer 430, so that the two can generate a good bonding reaction and generate a larger bonding force when bonded.

Taking the light-permeable medium layer 430 as an example, in this embodiment, before bonding the lower surface of the silicon base layer 511 or the upper surface of the silicon base layer 511 to the upper surface of the light-permeable medium layer 430, the method further includes: the lower surface of the silicon base layer 511 or the upper surface of the silicon base layer 511 is processed such that the lower surface or the upper surface of the silicon base layer 511 is made of a silicon dioxide material.

In a specific implementation, oxygen ions may be implanted into the upper surface or the lower surface of the silicon base layer 511 to form a silicon dioxide layer on the upper surface or the lower surface of the silicon base layer 511, so that the upper surface or the lower surface of the transfer member 500 is formed of silicon dioxide. It should be understood that the silicon substrate layer 511 has a regular crystal orientation structure, and therefore, the silicon dioxide layer also has a regular crystal orientation structure, so as to facilitate the bonding effect with the light-permeable medium layer 430.

Of course, in other embodiments of this specific example, a bonding layer 520 may be further stacked on the surface of the silicon base layer 511, wherein the bonding layer 520 is made of a silicon dioxide material, and the bonding layer 520 is formed by, for example, a non-metal vapor deposition process to be stacked on the upper surface or the lower surface of the silicon base layer 511, so as to improve the bonding strength between the transfer member 500 and the spectrum chip semi-finished product 400 by the bonding layer 520.

It should be noted that, in this specific example, the process of treating the surface of the transfer member 500 may also be completed in the step of providing the transfer member 500, and this is not a limitation of the present application. That is, the process of treating the upper surface or the lower surface of the silicon base layer 511 may be completed at the stage of preparing the transfer member 500.

As shown in fig. 12, the preparation process of the spectrum chip further includes: at least a portion of the target transfer layer 510 of the transfer member 500 is retained. It is to be understood that, in the method of manufacturing the spectrum chip of this specific example, the transfer member 500 has only the target transfer layer 510, i.e., the silicon base layer, as compared with the specific examples 3 and 4. Therefore, if the thickness or the surface characteristics of the silicon base layer 511 meet the predetermined requirements, the preparation process of the next stage is performed without any treatment to the silicon base layer 511.

Of course, in order to obtain more surface characteristics and to make the thickness dimension of the silicon base layer 511 meet preset requirements, in this particular example, a portion of the silicon base layer 511 may be removed and at least a portion of the silicon base layer 511 may be retained.

In this particular example, the silicon base layer 511 may be removed by one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes to optimize the surface characteristics of the remaining silicon base layer 511 and reduce the thickness dimension of the silicon base layer 511.

It is worth mentioning that the mechanical grinding has high efficiency but poor precision, while the chemical mechanical polishing and etching processes have low efficiency but high precision, so in this specific example, it is preferable to perform the first stage of treatment on the silicon base layer 511 by mechanical grinding and polishing, and then perform the second stage of treatment on the silicon base layer 512 by chemical mechanical polishing or etching processes to achieve both efficiency and precision.

In particular, in this specific example, the spectroscopic chip has certain requirements on the thickness of the silicon substrate layer 511, and the thickness of the silicon substrate layer 511 ranges from 5nm to 1000nm, preferably from 50nm to 750nm, and the thickness is favorable for processing the silicon substrate layer 511 by thickness, so that the imaging effect of the spectroscopic chip is optimized and ensured. More preferably, the thickness dimension of the silicon base layer 511 is between 150nm and 250 nm.

As shown in fig. 12, the process of manufacturing the optical device further includes: forming the light modulation structure 501 on the silicon substrate layer 511 which is reserved, so that the silicon substrate layer 511 is provided with the light modulation structure 501, and thus when external imaging light enters the inside of the spectrum chip through the silicon substrate layer 511, the silicon substrate layer 511 provided with the light modulation structure 501 can modulate the imaging light to extract and utilize spectrum information in the imaging light. It will be appreciated by those skilled in the art that the light modulation structure 501 is essentially a specific pattern formed in the silicon base layer 511 for performing a specific modulation process on the image light through the specific pattern.

In particular, in this particular example, the refractive index of the light modulating structure 501 is between 1 and 5, and the difference between the refractive index of the light modulating structure 501 and the refractive index of the light permeable medium layer 430 is greater than or equal to 0.5, preferably greater than or equal to 0.7, so that light of a relatively large range of wavelengths can pass through the light permeable medium layer 430 and the image sensing layer 410 of the spectral chip after passing through the light modulating structure 501.

In this particular example implementation, the light modulating structure 501 may be formed on the silicon base layer 511 by an etching process, a nano-imprinting process, or the like. Accordingly, after the light modulation structure 501 is formed, the spectrum chip is prepared. The specific process flow of the nano silk-screen printing process is as follows: firstly, coating a photosensitive material (such as photoresist) on the surface of a metal film on a wafer; then, a template having a filter pattern engraved thereon is pressed, and particularly, the template is transparent; then, ultraviolet light (UV light) is irradiated thereto to harden the photoresist on which the template pattern has been printed. The patterned photoresist is then visible by stripping the template.

It should be appreciated that in this particular example, the atoms within the silicon base layer 511 have a regular distribution of crystal orientations, and the internal structure of the silicon base layer 511 is not changed when being migrated to the surface of the spectroscopic chip semi-finished product 400 by the preparation method as described above. Therefore, the spectral chip manufactured by the manufacturing method disclosed in this embodiment has an optical layer structure with a better crystal orientation arrangement formed on the surface thereof.

In summary, the spectroscopic chip and the manufacturing method thereof based on this specific example are illustrated, which migrate the silicon substrate layer 511 with a preferred crystal orientation arrangement to the surface of the spectroscopic chip semi-finished product 400 in a specific manufacturing method, so that the surface of the spectroscopic chip finally manufactured has an optical layer structure with a preferred crystal orientation arrangement.

It is worth mentioning that in other variant implementations of this specific example, before the transfer member 500 is transferred to the spectrum chip semi-finished product 400 through the bonding process, the silicon base layer 511 of the transfer member 500 is pretreated to form the light modulation structure 501 in the silicon base layer 511, and the effect is shown in fig. 13, wherein the thickness of the silicon base layer is 200-. Accordingly, when the silicon substrate layer 511 is subsequently bonded to the surface of the spectrum chip semi-finished product 400, the light modulation structure 501 is also synchronously transferred to the surface of the spectrum chip semi-finished product 400. That is, in this modified embodiment, the light modulation structure 501 is previously prepared on the transfer member 500, or the process of forming the light modulation structure 501 is adjusted forward.

Performance testing

Fig. 14 and 15 are graphs showing comparison of the performance of the spectral chip manufactured according to the manufacturing methods illustrated in this specific example 3, specific example 4, and specific example 5 with that of an existing spectral chip. As shown in fig. 14, the spectral chip manufactured according to the manufacturing method of this specific example has an extinction coefficient far superior to that of the existing spectral chip in a desired wavelength range, i.e., 350nm to 900 nm. As shown in fig. 15, the refractive index of the spectral chip manufactured according to the manufacturing method of this specific example is also far superior to that of the existing spectral chip in the desired wavelength range, i.e., 350nm to 900 nm.

Specific example 6

Fig. 16 illustrates a schematic view of yet another specific example of the optical device and the method of manufacturing the optical device according to an embodiment of the present application. As shown in fig. 16, in this specific example, the optical device is a spectrum chip, the optical device body 110 is a spectrum chip semi-finished product 400, and the purpose of the preparation method is to: and forming a target transfer layer 610 with a high refractive index on the surface of the spectrum chip semi-finished product 400, wherein the target transfer layer 610 is provided with a light modulation structure 601 for modulating the imaging light entering the spectrum chip so as to extract and utilize the spectrum information in the imaging light.

Here, the spectroscopic chip to which the present application relates is applied to a computational spectrometer, wherein the most significant difference between a computational spectrometer and a conventional spectrometer is the difference in optical filtering. In a conventional spectrometer, the filter used for wavelength selection is a bandpass filter. The higher the spectral resolution, the narrower and more filters of the passband must be used, which increases the bulk and complexity of the overall system. Meanwhile, when the spectral response curve is narrowed, the luminous flux is decreased, resulting in a decrease in the signal-to-noise ratio.

For a computational spectrometer, however, a broad spectrum filter is used for each filter, which makes the data detected by the computational spectrometer system look completely different from the original spectrum. However, by applying a computational reconstruction algorithm, the original spectrum can be recovered by computation. Since the broadband filter passes more light than the narrowband filter, the spectrometer can detect spectra from darker scenes. Furthermore, according to the compressive sensing theory, the spectral curve of the filter can be properly designed to recover the sparse spectrum with high probability, and the number of filters is much smaller than the desired number of spectral channels (recovering higher-dimensional vectors from lower-dimensional vectors), which is undoubtedly very advantageous for miniaturization. On the other hand, by using a larger number of filters, a regularization algorithm (lower dimensional vectors after noise reduction are obtained from higher dimensional vectors) can be used to reduce noise, which increases the signal-to-noise ratio and makes the overall system more robust.

In contrast, when a conventional spectrometer is designed, a filter (the effect of which is equal to that of an optical modulation structure of a spectrum chip) needs to be designed according to a required wavelength, so that light with a specific wavelength can be transmitted (generally, the filter is designed to enhance the projection of incident light with the specific wavelength, but incident light with a non-specific wavelength band cannot be projected, the resonance condition can be controlled by changing the period and the diameter of a structure such as a nano disc, and the central wavelength of the incident light capable of enhancing the projection is changed, so that the filtering characteristic is realized). That is, the conventional spectrometer needs to control the size and position accuracy of the light modulation structure during the design process, and needs to improve the transmittance of a specific wavelength. For computational spectrometers, however, it is desirable to be able to receive light over a wide range of wavelength bands (e.g., 350nm to 900nm), and therefore, to focus more on the refractive index at the time of design.

Accordingly, as previously described, in this example, the spectroscopic chip is fabricated in the fabrication method, that is, the target transfer layer 610 having high transmittance is formed on the surface of the spectroscopic chip semi-finished product 400, wherein the target transfer layer 610 has the light modulation structure 601, so that light of a relatively large range of wavelength band can be collected and utilized. In particular, in this particular example, the refractive index of the object transfer layer 610 is 2.3 or greater.

In this particular example, the spectroscopic chip blank 400 includes an image sensing layer 410 and a signal processing circuit layer 420 connected to the image sensing layer 410. It is worth mentioning that the spectrum chip semi-finished product 400 may also include other structures, and more specifically, in this example, the semi-finished product of the spectrum chip without the target transfer layer 610 having the light modulation structure 601 is referred to as the spectrum chip semi-finished product 400.

In this specific example, the spectrum chip semi-finished product 400 may be provided by a manufacturer, or may be obtained by processing an existing photosensitive chip. Those skilled in the art will appreciate that the conventional photo chip, such as a CCD photo chip, a CMOS photo chip, includes a microlens layer, a color filter layer (not including a color filter layer if a black and white chip is used), an image sensing layer 410, and a signal processing circuit layer 420. Accordingly, the spectrum chip semi-finished product 400 can be obtained by removing the microlens layer and the color filter layer of the existing photosensitive chip (if the chip is a black-and-white chip, only the microlens layer needs to be removed). That is, by applying the manufacturing method of the optical device according to the embodiment of the present application, the spectrum chip applied to the computing spectrometer can be manufactured using the existing photosensitive chip, thereby reducing the application cost.

As shown in fig. 16, in this specific example, the optical device manufacturing process includes first pre-treating the surface of the spectrum chip semi-finished product 400 to form a flat bonding surface on the surface of the spectrum chip semi-finished product 400 for bonding a transfer member having a target transfer layer 610.

Specifically, in this specific example, the process of preprocessing the surface of the spectrum chip semi-finished product 400 includes: a light-permeable medium layer 430 is formed on the surface of the spectrum chip semi-finished product 400, wherein the light-permeable medium layer 430 is made of a light-permeable material and has a relatively high light transmittance, so that it does not affect the light entering the spectrum chip semi-finished product 400.

It is worth mentioning that in the implementation, although the light-permeable medium layer 430 needs a relatively high refractive index, the refractive index of the light-permeable medium layer 430 is not too high, because: it is necessary to ensure a difference in refractive index between the light-permeable medium layer 430 and the semiconductor structure layer located thereon.

In this specific example, the light-permeable medium layer 430 is preferably made of silicide, such as silicon dioxide, silicon nitride, etc. Those skilled in the art will appreciate that silicon dioxide has a refractive index of about 1.45 and silicon nitride has a refractive index of between 1.9 and 2.3.

In a specific implementation, the light-permeable medium layer 430 may be formed on the surface of the spectrum chip semi-finished product 400 by a non-metal vapor deposition process, for example, but in other embodiments of this specific implementation, the light-permeable medium layer 430 may also be formed by other processes, and the formation process is not limited in this application. In particular, in this specific example, the thickness of the light-permeable medium layer 430 is not limited in this application, and the specific value thereof can be adjusted according to the specific requirements of the application scenario, and in general, the thickness is less than or equal to 300nm, and in some special scenarios, it is even less than 100nm,

as shown in fig. 16, in this specific example, the upper surface of the light-permeable medium layer 430 is preferably a flat surface, or the portion of the upper surface of the light-permeable medium layer 430 for combining with the transfer member has a relatively high flatness, so as to facilitate the transfer member to the spectrum chip semi-finished product 400.

It is worth mentioning that in some cases of this specific example, the surface of the spectrum chip semi-finished product 400 may be non-flat, and the upper surface of the light-permeable medium layer 430 formed on the surface of the spectrum chip semi-finished product 400 by the deposition process may also be non-flat. Therefore, in this embodiment, the preprocessing process further includes: and polishing and grinding the performance of the spectrum chip semi-finished product 400, and/or polishing and grinding the upper surface of the light-permeable medium layer 430. Here, the polishing process may be a chemical mechanical polishing (chemical mechanical polishing) process, or other processes capable of increasing the surface flatness, and the application is not limited thereto.

It is worth mentioning that, in this specific example, if the surface flatness of the spectrum chip semi-finished product 400 meets the preset requirement, the light-permeable medium layer 430 may not be disposed on the surface of the spectrum chip semi-finished product 400, that is, the spectrum chip semi-finished product 400 does not need to be pretreated.

Further, as shown in fig. 16, the process of manufacturing the optical device further includes: a transfer member 600 is provided. In particular, in this specific example, the transfer member 600 is a homemade semiconductor device, which includes, in order from bottom to top: a substrate 620 and the target transfer layer 610 formed on the substrate 620, wherein the substrate 620 is made of a chemically active relatively stable material, and the target transfer layer 610 is made of a material with high transmittance, including but not limited to tantalum oxide, titanium oxide, etc. Preferably, in this particular example, the surface of the target transfer layer 610 is a flat surface.

It will be appreciated by those skilled in the art that the higher the refractive index of the transfer target layer 610 is, the more advantageous it is for the light modulating structure 601 of the spectroscopy chip, but if the refractive index of the transfer target layer 610 is too high, process limitations may result in the thickness dimension of the transfer target layer 610 being unsatisfactory, particularly, in this particular example, the thickness dimension of the transfer target layer 610 is greater than 350 nm. Therefore, in this specific example, the transfer target layer 610 of the transfer member 600 is manufactured by a specific process so that the transfer target layer 610 can satisfy the thickness dimension requirement while having high transmittance.

Specifically, taking the example that the transition-target layer 610 is implemented as tantalum oxide, in a specific embodiment of this specific example, the transition-target layer 610 is formed by bonding. More specifically, first, a relatively thin tantalum oxide layer is formed on the substrate 620, for example, the tantalum oxide layer has a thickness dimension of 80 nm; next, other tantalum oxide layers are stacked on top of each other through a bonding process to obtain the target transfer layer 610 satisfying a predetermined thickness dimension requirement. That is, the layers are added layer by layer through the bonding process so that the thickness dimension of the finally obtained target transfer layer 610 satisfies a preset requirement, i.e., 350nm or more.

It is worth mentioning that before each bonding, the bonding surface may be ground flat to optimize the bonding effect.

As shown in fig. 16, the process of manufacturing the optical device further includes: the transfer member 600 is coupled to the spectroscopy chip blank 400 in such a manner that the upper surface of the transfer member 600 is bonded to the upper surface of the light-permeable medium layer 430 of the spectroscopy chip blank 400. That is, the transfer member 600 is transferred to the spectroscopic chip semi-finished product 400 in such a manner that the upper surface of the target transfer layer 610 of the transfer member 600 is bonded to the upper surface of the light-permeable medium layer 430 of the spectroscopic chip semi-finished product 400.

In order to ensure the bonding strength between the transfer member 600 and the spectrum chip semi-finished product 400, preferably, in the embodiment of the present application, the upper surface of the transfer member 600 and the upper surface of the light-permeable medium layer 430 have a good bonding reaction, so that the two surfaces can generate a good bonding reaction during bonding, and generate a larger bonding force. For example, in this particular example, the upper surface of the transfer member 600 is configured to be made of the same material as the light-permeable medium layer 430, so that the two can generate a good bonding reaction and generate a larger bonding force when bonding.

Taking the light-permeable medium layer 430 as an example of silicon dioxide, it should be understood that in this particular example, the upper surface of the transfer member 600 is formed by the upper surface of the target transfer layer 610. Therefore, in this implementation, a bonding layer 630 may be stacked on the upper surface of the target transfer layer 610, wherein the bonding layer 630 is made of a silicon dioxide material, and the bonding layer 630 is formed by, for example, a non-metal vapor deposition process, being stacked on the surface of the target transfer layer 610, so as to improve the bonding strength between the transfer member 600 and the spectroscopic chip semi-finished product 400 by the bonding layer 630.

It should be noted that, in this specific example, the process of processing the bonding surface of the transfer member 600 may also be completed in the step of providing the transfer member 600, and this is not a limitation of the present application.

As shown in fig. 16, the process of manufacturing the optical device further includes: the target transfer layer 610 of the transfer 600 is retained. In this particular example, the substrate 620 may be removed using one or a combination of mechanical grinding, chemical mechanical polishing, and etching processes, such that the target transfer layer 610 of the transfer 600 remains.

It is worth mentioning that the mechanical grinding has high efficiency but poor precision, while the chemical mechanical polishing and etching processes have low efficiency but high precision, so in this specific example, it is preferable to perform the first stage of processing on the substrate 620 by mechanical grinding and polishing, and then perform the second stage of processing on the substrate 620 by chemical mechanical polishing or etching processes to achieve both efficiency and precision.

Accordingly, in this particular example, to meet the thickness requirement, in the process of removing the substrate 620, further comprises removing a portion of the targeted transfer layer 610, so that the thickness dimension of the targeted transfer layer 610 meets the preset requirement.

As shown in fig. 16, the process of manufacturing the optical device further includes: forming a light modulation structure 601 on the reserved target transfer layer 610, so that the target transfer layer 610 has the light modulation structure 601, and thus, when external imaging light enters the inside of the spectrum chip through the target transfer layer 610, the target transfer layer 610 with the light modulation structure 601 can modulate the imaging light to extract and utilize spectrum information in the imaging light. As one of ordinary skill in the art will appreciate, the light modulation structure 601 is essentially a specific pattern formed in the target transfer layer 610 for performing a specific modulation process on the imaging light through the specific pattern.

In particular, in this specific example, the refractive index of the light modulation structure 601 is 2.3 or more, and the difference between the refractive index of the light modulation structure 601 and the refractive index of the light-permeable medium layer 430 is 0.5 or more, preferably 0.7 or more, so that light of a relatively large range of wavelengths can pass through the light-permeable medium layer 430 and the image sensing layer 410 of the spectrum chip after passing through the light modulation structure 601.

In this particular exemplary implementation, the light modulating structure 601 may be formed within the transfer target layer 610 by an etching process, a nanoimprinting process, or the like. Accordingly, after the light modulation structure 601 is formed, the spectroscopic chip is completed. The specific process flow of the nano silk-screen printing process is as follows: firstly, coating a photosensitive material (such as photoresist) on the surface of a metal film on a wafer; then, a template having a filter pattern engraved thereon is pressed, and particularly, the template is transparent; then, ultraviolet light (UV light) is irradiated thereto to harden the photoresist on which the template pattern has been printed. The patterned photoresist is then visible by stripping the template.

It should be appreciated that in this particular example, the target transfer layer 610 of the transfer member 600 has a relatively high refractive index, and the internal structure of the target transfer layer 610 is not altered when transferred to the surface of the spectroscopic chip blank 400 by the fabrication method described above. Therefore, the spectral chip manufactured according to the manufacturing method disclosed in this embodiment has an optical layer structure with a higher refractive index formed on the surface thereof.

In summary, the spectroscopic chip and the manufacturing method thereof based on this specific example are illustrated, which migrate the target transfer layer 610 (including but not limited to tantalum oxide layer, titanium oxide layer) with higher refractive index to the surface of the spectroscopic chip semi-finished product 400 in a specific manufacturing method, so that the surface of the spectroscopic chip finally manufactured has the optical layer structure with higher refractive index.

It is worth mentioning that in some variant implementations of this particular example, a portion of the substrate 620 in the transfer 600500 may also be retained, i.e. in this variant implementation, only at least a portion of the substrate 620 is removed, so that a portion of the substrate 620 and the target transfer layer 610 are retained. Here, the substrate 620 that is left can provide a certain protection effect to the target transfer layer 610. Accordingly, during the subsequent formation of the light modulating structure 601, the remaining substrate 620 is also partially etched, which has the final shaping effect, as shown in FIG. 17.

It is further worth mentioning that in other modified implementations of this specific example, before the transfer member 600 is transferred to the spectrum chip semi-finished product 400 through the bonding process, the target transfer layer 610 of the transfer member 600 is pretreated to form the light modulation structure 601 in the target transfer layer 610, and the effect is shown in fig. 18, wherein the thickness dimension of the target transfer layer 610 is greater than or equal to 350 nm. Accordingly, when the targeted transfer layer 610 is subsequently retained, the light modulating structure 601 of the targeted transfer layer 610 is also simultaneously retained. That is, in this modified embodiment, the light modulation structure 601 is previously prepared in the target transfer layer 610 of the transfer member 600, or the process of forming the light modulation structure 601 is adjusted forward.

Fig. 19 illustrates a schematic view of another modified implementation of the optical device and the method for manufacturing the optical device illustrated in specific example 6. As shown in fig. 19, in this modified implementation of this specific example, the transfer-target layer 610 includes a plurality of sub-transfer layers 611 stacked on top of each other, wherein, during the preparation process, each sub-transfer layer 611 is respectively formed on the upper surface of the light-permeable medium layer 430 by a bonding process in a stacked manner.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (21)

1. A method of making an optical device, comprising:

providing a transfer piece and an optical device to be transferred, wherein the transfer piece comprises a target transfer layer with a regular crystal orientation structure;

forming a light-permeable medium layer on the surface of the optical device to be transferred;

coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred; and

leaving at least a portion of the target transfer layer of the transfer member to form an optical device.

2. The method of claim 1, wherein the upper surface of the light-transmissive medium layer is a flat surface.

3. The method of claim 2, wherein forming a light-permeable medium layer on the surface of the optical device to be transferred comprises:

depositing the light-permeable medium layer on the surface of the optical device to be transferred by a vapor deposition process; and

and processing the upper surface of the light-permeable medium layer so as to enable the upper surface of the light-permeable medium layer to be a flat surface.

4. The method of claim 3, wherein prior to depositing the light-permeable medium layer on the surface of the optical device to be transferred by a vapor deposition process, further comprising:

and pretreating the surface of the optical device to be transferred to ensure that the part of the surface of the optical device to be transferred, which is used for depositing the light-permeable medium layer, is a flat surface.

5. The method of manufacturing an optical device according to claim 3, wherein treating the upper surface of the light-permeable medium layer so that the upper surface of the light-permeable medium layer is a flat surface comprises:

and polishing and grinding the upper surface of the light-permeable medium layer by a chemical mechanical polishing process so as to enable the upper surface of the light-permeable medium layer to be a flat surface.

6. The method of manufacturing an optical device according to claim 1, wherein the transfer member further comprises a bonding layer formed on a surface of the target transfer layer, the bonding layer and the light-permeable medium layer having the same material of manufacture;

wherein coupling the transfer member to the optical device to be transferred in such a manner that the target transfer layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred comprises:

coupling the transfer member to the optical device to be transferred in such a manner that the bonding layer formed on the surface of the target transfer layer is bonded to the light-permeable medium layer of the optical device to be transferred.

7. The method of fabricating an optical device according to claim 1, wherein coupling the transfer member to the optical device to be transferred in such a manner that the transfer target layer of the transfer member is bonded to the light-permeable medium layer of the optical device to be transferred comprises:

forming a bonding layer on a surface of the target transfer layer of the transfer member, the bonding layer and the light-permeable medium layer having the same material; and

coupling the transfer member to the optical device to be transferred in such a manner that the bonding layer formed on the surface of the target transfer layer is bonded to the light-permeable medium layer of the optical device to be transferred.

8. The method for manufacturing an optical device according to claim 7, wherein forming a bonding layer on a surface of the target transfer layer of the transfer member includes:

treating a surface of the target transfer layer to form the bonding layer on the surface of the target transfer layer of the transfer member, the bonding layer being made of the same material as the light-permeable medium layer.

9. The method for manufacturing an optical device according to claim 7, wherein forming a bonding layer on a surface of the target transfer layer of the transfer member includes:

and superposing the bonding layer on the surface of the target transfer layer, wherein the bonding layer and the light-permeable medium layer are made of the same material.

10. The method of manufacturing an optical device according to claim 1, wherein retaining at least a portion of the target transfer layer of the transfer member to form an optical device comprises:

removing portions of the transfer member other than the target transfer layer to leave the target transfer layer of the transfer member to form the optical device.

11. The method of manufacturing an optical device according to claim 1, wherein retaining at least a portion of the target transfer layer of the transfer member to form an optical device comprises:

removing portions of the transfer member other than the target transfer layer and at least a portion of the target transfer layer to leave at least a portion of the target transfer layer to form the optical device.

12. The method for manufacturing an optical device according to claim 1, wherein the target transfer layer is a silicon crystal layer.

13. The method of manufacturing an optical device according to claim 1, wherein the target transfer layer is a silicide layer.

14. The method of manufacturing an optical device according to claim 1, wherein the optical device to be transferred is a semi-finished product of a spectroscopic chip, and the optical device is a spectroscopic chip.

15. The method of manufacturing an optical device according to claim 14, wherein the semi-finished spectroscopic chip comprises an image sensor and a signal processing circuit layer.

16. A method of making an optical device according to claim 15, wherein retaining at least a portion of the target transfer layer of the transfer member to form an optical device comprises:

forming a light modulating structure on the retained target transfer layer to form the optical device.

17. The method of making an optical device according to claim 15, wherein the target transfer layer of the transfer member has a light modulating structure formed therein.

18. The method for manufacturing an optical device according to claim 1, wherein the transfer member is an SOI device, and the target transfer layer is a silicon crystal layer of the SOI device.

19. The method of making an optical device according to claim 12, wherein providing a transfer member comprises:

providing a monocrystalline silicon structure; and

processing the single-crystal silicon structure to form the silicide layer within the single-crystal silicon structure to form the transfer.

20. The method of making an optical device according to claim 13, wherein providing a transfer member comprises:

providing a substrate layer; and

the silicide layer is stacked on the base layer to form the transfer.

21. An optical device produced by the production method according to any one of claims 1 to 20.

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