Patent Application
20250199375
The present invention relates to the field of semiconductor technology, and more specifically, to an electro-optical modulator and manufacturing method thereof.
In the field of photonic computing, improving the energy efficiency ratio is a significant issue. The electro-optical modulator is the most critical device for realizing photonic computing, as well as a highly reused component in optoelectronic chips, with typically thousands or even tens of thousands integrated into a single chip. Reducing its power consumption in the modulator is one of the key factors in improving the energy efficiency of photonic computing.
Currently, silicon photonic chips commonly use modulators based on carrier dispersion effects. The modulation methods include carrier injection (forward bias) and depletion (reverse bias). The modulator types include micro-ring modulators or Mach-Zehnder interferometers (MZI). However, micro-ring modulators are sensitive to wavelength and temperature, making it difficult to achieve high-precision computation. Additionally, their overall power consumption remains high due to the need for additional heating and feedback control circuits. Injection-type MZIs offer high modulation efficiency and are suitable for high-density integration but generate a significant direct current (on the milliampere level) during operation, resulting in high static power consumption. Depletion-type MZIs exhibit lower modulation efficiency and require larger size. Furthermore, the presence of terminal loads in depletion-type MZIs limits their suitability for photonic computing, both in terms of power consumption and integration density.
The present invention provides an electro-optical modulator and a method for its manufacture, facilitating the integration of a compact, highly efficient, and low-power electro-optical modulator into a silicon photonic chip.
Embodiments of the invention provide an electro-optical modulator comprising a hybrid waveguide including stacked silicon and nonlinear optical material layers, and an electrode including a first electrode and a second electrode disposed on both sides of the hybrid waveguide. The electro-optical modulator further comprises coupling ends extending from both ends of the hybrid waveguide for optical coupling, with at least one of these coupling ends including a tapered structure.
In some embodiments, the nonlinear optical material layer includes at least one of the following: a barium titanate layer, a lithium niobate layer, a lithium tantalate layer, and an organic polymer layer. Additionally, or alternatively, the silicon layer includes at least one of a monocrystalline silicon layer and a silicon nitride layer.
In some embodiments, the vertical projection of the silicon layer in the hybrid waveguide is within the vertical projection range of the nonlinear optical material layer.
In some embodiments, the tapered structure comprises a base section connected to the hybrid waveguide and comprising stacked silicon and nonlinear optical material layers, optionally with the silicon and nonlinear optical material layers of the base section matching the sizes of the silicon and nonlinear optical material layers of the hybrid waveguide. The tapered structure further comprises a deformed section connected to the base section and comprising stacked silicon and nonlinear optical material layers, wherein the nonlinear optical material layer of the deformed section extends from the base section's nonlinear optical material layer and gradually decreases in size away from the base section, while the silicon layer of the deformed section extends from the base section's silicon layer and remains unchanged in size.
In other embodiments, the tapered structure comprises a base section, connected to the hybrid waveguide and comprising stacked silicon and nonlinear optical material layers; an intermediate section, connected to the base section and comprising stacked silicon and nonlinear optical material layers; and a deformed section, connected to the intermediate section and comprising stacked silicon and nonlinear optical material layers. Wherein the silicon layer of the intermediate section comprises silicon layers extending from both the deformed and base sections, with the silicon layer extending from the deformed section positioned above the silicon layer extending from the base section. Additionally, the nonlinear optical material layer of the deformed section extends from the intermediate section's nonlinear optical material layer and gradually decreases in size away from the intermediate section.
In some embodiments, the end face of the nonlinear optical material layer in the deformed section includes an inclined surface.
In some embodiments, when viewed from above, the inclined surface of the nonlinear optical material layer in the deformed section forms an angle with the silicon layer in the same section. Optionally, the angle is less than 45°.
In some embodiments, in the intermediate section, the thickness of the silicon layer extending from the deformed section is greater than that of the silicon layer extending from the base section.
In some embodiments, in the intermediate section, the width of the silicon layer extending from the deformed section is smaller than that of the silicon layer extending from the base section.
In some embodiments, when viewed from above, in the intermediate section, the width of the silicon layer extending from the base section initially gradually increases and then gradually decreases along the extension direction.
In some embodiments, when viewed from above, in the intermediate section, the width of the tail end of the silicon layer extending from the deformed section gradually decreases along the extension direction.
In some embodiments, the electro-optical modulator comprises at least two hybrid waveguides, at least one beam splitter, and at least one beam combiner. The output end of the beam splitter is connected to the coupling end at the input side of the corresponding hybrid waveguide via a first connecting waveguide, and the input end of the beam combiner is connected to the coupling end at the output side of the corresponding hybrid waveguide via a second connecting waveguide.
Additionally, embodiments of the present invention provide a method for manufacturing an electro-optical modulator. The method is suitable for manufacturing the electro-optical modulator described in any of the embodiments above, comprising a hybrid waveguide with electrodes positioned on either side of the waveguide. The method comprises: providing a first component, which at least includes a silicon layer and conductive wiring structures located on both sides of the silicon layer; providing a second component, which includes a nonlinear optical material layer and conductive wiring structures located on both sides of the nonlinear optical material layer; and bonding the first component to the second component to form the electro-optical modulator, wherein the silicon layer and the nonlinear optical material layer are stacked to form the hybrid waveguide, and the conductive wiring structures on both sides of the silicon layer are electrically connected to those on both sides of the nonlinear optical material layer, thereby forming the electrodes.
In some embodiments, the nonlinear optical material layer includes at least one of the following: a barium titanate layer, a lithium niobate layer, a lithium tantalate layer, and an organic polymer. The silicon layer includes at least one of a monocrystalline silicon layer and a silicon nitride layer.
In some embodiments, the hybrid waveguide includes a first hybrid waveguide formed by stacking a monocrystalline silicon layer over a barium titanate layer. Optionally, the hybrid waveguide includes a second hybrid waveguide formed by stacking a silicon nitride layer over a lithium niobate layer.
In some embodiments, providing the first component comprises: forming a first element using a front-end-of-line process, wherein the first element comprises the silicon layer; performing a thinning treatment on a side of the first element adjacent to the silicon layer; and forming conductive wiring structures on both sides of the region corresponding to the silicon layer in the thinned first element, thereby obtaining the first component.
In some embodiments, providing the second component comprises: forming a nonlinear optical material layer on a wafer; removing the nonlinear optical material from areas outside of a predetermined region, with a nonlinear optical material layer in the predetermined region retained, thereby obtaining a second element, wherein the predetermined region corresponds to the area for overlap with the silicon layer; depositing a silicon oxide layer on top of the second element to obtain a third element; and forming conductive wiring structures on both sides of the region corresponding to the retained nonlinear optical material layer in the third element, thus obtaining the second component.
In some embodiments, the conductive wiring structures comprise conductive structures within holes.
In some embodiments, the method further comprises forming bonding structures on at least one surface of the electro-optical modulator, which is formed by bonding the first component to the second component, for bonding with additional components.
According to the aforementioned embodiments, the present invention utilizes front-end-of-line processes to fabricate the first component, which can be a photonic integrated circuit chip. Nonlinear optical materials, such as barium titanate, lithium niobate, lithium tantalate, or organic polymers, are used to fabricate the second component, like a barium titanate thin film or a lithium niobate thin film. Back-end-of-line processes (e.g., wafer bonding, through-hole wiring, etc.) are then employed to combine the barium titanate thin film or lithium niobate thin film with the photonic integrated circuit chip. The resulting modulator is capacitive, with very small capacitance, making it extremely easy to drive, with no static power consumption and very low dynamic power consumption. Therefore, the present invention enables the integration of compact, high-efficiency, and low-power electro-optical modulator technologies, which may be incompatible with traditional Complementary Metal-Oxide-Semiconductor (CMOS) processes, into classical silicon-based optoelectronic processes.
Aspects, features, advantages and the like of the embodiments will be described in greater detail by reference to the drawings. The aspects, features, advantages and the like will be apparent according to the detailed description by reference to the drawings.
To facilitate understanding of the various aspects, features, and advantages of the technical solutions of the present invention, the following specific description is provided in conjunction with the accompanying drawings. It should be understood that the various embodiments described below are for illustrative purposes only and are not intended to limit the scope of protection of the present invention.
The terms “comprising,” “comprise,” “including,” “include,” or similar terms used herein are open-ended and should be interpreted as “including but not limited to.” The term “approximately” or similar terms refer to an acceptable range of error, within which a person skilled in the art can address the technical problem and achieve a substantially similar technical effect.
Additionally, the terms “connection,” “connected,” “connecting,” or the like encompasses both direct and indirect means of connection. Therefore, if a first device is described as being connected to a second device, it indicates that the first device may be directly connected to the second device or indirectly connected through other devices.
The terms “first,” “second,” and so on, are used to distinguish between different devices, modules, or structures and do not indicate order or imply that “first” and “second” are of different types. Furthermore, in the description, claims, and drawings of the application, certain processes are described with multiple operations, steps, or procedures in a specific sequence. These operations, steps, or procedures may be executed in an order different from their appearance in the document or may be performed in parallel. Step numbers such as S1, S2, etc., are merely used to differentiate between different operations and do not imply any execution order. Additionally, these processes may include more or fewer operations, and these operations can be performed sequentially or in parallel.
In the embodiments of the present invention, an electro-optical modulator comprises a hybrid waveguide with a first electrode and a second electrode positioned on both sides of the hybrid waveguide. The hybrid waveguide comprises stacked silicon and nonlinear optical material layers. The electro-optical modulator further comprises coupling ends extending from both ends of the hybrid waveguide for optical coupling, with at least one of these coupling ends including a tapered structure. One of the coupling ends is used to introduce an optical signal (e.g., optical wave) into the hybrid waveguide, while the other is used to output the optical signal (e.g., optical wave) from the hybrid waveguide. In an optional embodiment, both coupling ends of the hybrid waveguide adopt the tapered structure. In some embodiments, the nonlinear optical material layer comprises at least one of the following: barium titanate (BTO) layer, lithium niobate layer, lithium tantalate layer, or an organic polymer layer. Additionally, or alternatively, the silicon layer may include at least one of a monocrystalline silicon (C-Si) layer or a silicon nitride layer.
In some embodiments, the electro-optical modulator comprises at least two hybrid waveguides, at least one beam splitter, and at least one beam combiner. The output end of the beam splitter is connected to the coupling end at the input side of the corresponding hybrid waveguide via a first waveguide for connection, and the input end of the beam combiner is connected to the coupling end at the output side of the corresponding hybrid waveguide via a second waveguide for connection.
In the embodiments shown in
In the embodiments shown in
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In some embodiments, as shown in
As shown in
In some embodiments, the thickness of the second silicon layer is greater than that of the first silicon layer. In the intermediate section 1003, the second silicon layer is located above the first silicon layer. Optionally, the thickness of the first silicon layer is typically around 70 to 150 nm. In other embodiments, the thickness of the second silicon layer can be the same as or smaller than that of the first silicon layer. In some embodiments, when viewed from above, the width of the first silicon layer extending from the base section 1001 in the intermediate section 1003 first increases and then decreases along its extension direction, while the width of the second silicon layer extending from the deformed section 1002 gradually decreases along its extension direction. In alternative embodiments, the width of the first silicon layer extending from the base section 1001 remains constant along the extension direction. Alternatively, the width of the second silicon layer extending from the deformed section 1002 remains unchanged. In other embodiments, the width of the first silicon layer extending from the base section 1001 in the intermediate section 1003 is greater than the width of the second silicon layer extending from the deformed section 1002.
The nonlinear optical material layer in the deformed section 1002 extends from the nonlinear optical material layer in the intermediate section 1003, and its size gradually decreases in the direction away from the intermediate section. In some embodiments, as shown in
According to the above embodiments, Tapered Structure Example 1 is applicable in cases where the thickness of the silicon layer in the hybrid waveguide matches the thickness of the silicon layer in the connection waveguide, whereas Tapered Structure Example 2 is suitable for cases where the silicon layer in the hybrid waveguide is further thinned.
In various embodiments of the present invention, the hybrid waveguide serves as the main region for achieving electro-optic modulation. In traditional silicon-based modulators, the refractive index is adjusted by modulating the carrier distribution through applied voltage or current signals, thereby affecting the effective refractive index of the mode field. In contrast, the operating mechanism of the hybrid waveguide relies on the nonlinear optical effect of the nonlinear optical material, wherein the refractive index of the material is adjusted by the intensity of the applied electric field, while the refractive index of the silicon layer remains unchanged. For example, in a BTO-Si hybrid waveguide, based on the nonlinear optical effect of the BTO material, the refractive index of the BTO material is modulated by varying the applied electric field, such that the overlap between the optical mode and the BTO layer affects the modulation efficiency. The greater the overlap, the more significant the influence of the BTO material on the effective refractive index, resulting in higher modulation efficiency. To adjust the overlap, the thickness of the silicon layer can be modified, while its width is selected based on wavelength requirements. Generally, the thinner the silicon layer in the hybrid waveguide, the more the mode field is distributed in the BTO material, resulting in higher efficiency.
In some embodiments, the coupling end of Example 1 of the hybrid waveguide is suitable for using the aforementioned Tapered Structure Example 1, while the coupling end of Example 2 of the hybrid waveguide is suitable for using Tapered Structure Example 2. In alternative embodiments, Tapered Structure Example 1 can also be suitable for the hybrid waveguide in Example 2, and Tapered Structure Example 2 can be suitable for the hybrid waveguide in Example 1.
The following describes the method for manufacturing an electro-optical modulator, which is suitable for producing the electro-optical modulator of any of the aforementioned embodiments or examples. For clarity, the example illustrates only one hybrid waveguide.
In an embodiment of the present invention, the method for manufacturing an electro-optical modulator, which at least includes a hybrid waveguide with electrodes located on both sides of the hybrid waveguide, comprises the following steps:
In some embodiments, the first component includes a Photonic Integrated Circuit (PIC) chip and an interlayer dielectric (ILD). In step S1, the first component can be fabricated using the front-end-of-line (FEOL) processes for the PIC in a commercial wafer fab. The first component comprises the silicon layer and conductive wiring structures, with the silicon layer including at least one of a monocrystalline silicon layer (C-Si) or a silicon nitride layer. In some embodiments, the first component may also comprise one or more other optical devices in addition to the silicon layer and conductive wiring structures.
In some embodiments, independently of step S1, step S2 involves depositing a certain thickness of a nonlinear optical material layer and conductive wiring structures onto a silicon-on-insulator (SOI) wafer to form the second component. The nonlinear optical material layer comprises at least one of the following: barium titanate (BTO), lithium niobate, lithium tantalate, or organic polymer. It should be understood that step S2 is independent of step S1, and there is no dependency between the two. Step S1 can be carried out before step S2, or step S2can be carried out before step S1. Alternatively, steps S1 and S2 can be performed in parallel to improve production efficiency.
In some embodiments, in step S3, during back-end-of-line (BEOL) processes of the PIC, the first component is directly bonded to the second component using a wafer bonding process to form the electro-optical modulator. The silicon layer and the nonlinear optical material layer are stacked together to form the hybrid waveguide. In some embodiments, the hybrid waveguide is formed by stacking a monocrystalline silicon layer (C-Si) over a barium titanate (BTO) layer. Alternatively, the hybrid waveguide can be formed by stacking a silicon nitride layer over a lithium niobate layer.
The electro-optical modulator produced by the above process is capacitive, with an extremely small capacitance, making it very easy to drive, requiring no static power consumption, and exhibiting very low dynamic power consumption. Compared to existing modulators, the electro-optical modulator offers lower energy consumption and a more compact size.
In an exemplary embodiment, in step S1, providing the first component includes the following procedures:
The first component 100 is obtained through the above three processes. In this embodiment, the first component 100 can be a photonic integrated circuit (PIC) chip that includes the monocrystalline silicon layer 101 and other optical devices. For example, other optical devices may comprise a germanium-silicon photodetector (Ge-Si PD) 102, a modulator based on carrier dispersion effects, or a Variable Optical Attenuator (VOA) 103, and connecting waveguides (e.g., silicon waveguides).
In an exemplary embodiment, in step S2, providing the second component includes the following procedures:
As shown in
In an exemplary embodiment, in step S3, during the back-end-of-line process of the PIC, the first component 100 and the second component 200 are directly bonded together using a wafer bonding process to obtain the electro-optical modulator. In some embodiments, as shown in
In some embodiments, as shown in
It should be understood by those skilled in the art that although the above embodiment mainly describes the nonlinear optical material as BTO, the present invention is not limited to this. The nonlinear optical material may also be lithium niobate, lithium tantalate, organic polymer, etc.
It should be understood by those skilled in the art that the above disclosure is illustrative of the invention's embodiments and does not limit the scope of patent protection sought by this application. Equivalent variations made based on the embodiments of the invention are still within the scope covered by the claims of this application.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202210276684.2 | Mar 2022 | CN | national |
This application is a U.S. National Phase of International Application Number PCT/CN2023/079471 filed on Mar. 3, 2023, which claims the benefit of, and priority to, the Chinese Patent Application No. 202210276684.2, titled “Electro-optical Modulator and Manufacturing Method Thereof,” filed on Mar. 21, 2022, which is herein incorporated by reference in its entirety.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2023/079471 | 3/3/2023 | WO |
