JP2012042849A - Optical waveguide device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To monolithically integrate a silica optical waveguide element and a silicon optical waveguide element and connect those devices together with low loss.SOLUTION: The optical waveguide device includes: an optical function element including a silica optical waveguide 103; an optical function element including a silicon narrow line optical waveguide 102; and a spot size converter 101 which connects the optical function element including the silica optical waveguide 103 with the optical function element including the silicon narrow line optical waveguide 102. The optical function element including the silica optical waveguide 103, the optical function element including the silicon narrow line optical waveguide 102, and the spot size converter 101 are monolithically integrated on the same substrate. A core of the silica optical waveguide 103 and a first overclad layer of the silicon narrow line optical waveguide 102 are formed of a film of the same layer on the substrate.

Description

  The present invention relates to an optical waveguide device in which optical functional elements necessary for construction of an optical communication network are integrated in one optical circuit chip.

Wavelength multiplexing is an important technology in optical communication technology that supports high-speed and large-capacity communication networks. For example, ROADM (reconfigurable optical add / drop multiplexer) technology that combines wavelength multiplexing transmission technology and transmission path management technology Is mentioned.
For the construction of an optical communication network to which ROADM technology is applied, a wavelength multiplexer / demultiplexer using an arrayed waveguide diffraction grating (AWG) and a variable optical attenuator (VOA) provided for each wavelength channel constitute one optical circuit. An optical device called VMUX integrated on a chip is used.

The current VMUX is configured based on a silica-based optical waveguide whose core and clad are made of a silica-based material. Silica-based optical waveguide elements are widely used as optical circuits, and have excellent characteristics such as low loss and high reliability (see Non-Patent Document 1).
As a VOA with low power consumption, there is an element based on the principle of free carrier absorption in a silicon fine wire optical waveguide (see Non-Patent Document 2).

Mark Earnshaw, C. Bolle, MACappuzzo, E. Chen, L. Gomez, and A. Wong-Foy, “Compact 64 Channel, 100GHz VMUX with Low-Power, Fast Attenuators”, Page IWC3, Integrated Photonics and Nanophotonics Research and Applications (IPNRA), Salt Lake City, Utah, July 8, 2007, Planer Lightwave Circuits (IWC) K. Yamada, T. Tsuchizawa, T. Watanabe, H. Fukuda, H. Shinojima, S. Itabashi, “Applications of Low-loss Silicon Photonic Wire Waveguides with Carrier Injection Structures”, 4th IEEE International Conference on Group IV Photonics, pp .116-118, Sept. 2007

However, the VMUX configured based on the quartz optical waveguide has the following problems.
In other words, a Mach-Zehnder interferometer equipped with a phase shifter based on the thermo-optic effect is used as the VOA. It takes several milliseconds for the light attenuation operation, and the element size is large, and the number of channels is large. When the number increases, the device size increases and the power consumption increases.

  On the other hand, as a VOA that can operate at high speed, has a small element size, and low power consumption, there is an element based on the principle of free carrier absorption in a silicon fine wire optical waveguide. However, when such a VOA is used, it is necessary to connect the silicon optical waveguide and the silica-based optical waveguide with low loss. However, the silicon optical waveguide and the silica-based optical waveguide should be monolithically integrated on the same substrate. There was a problem that was difficult.

  The present invention has been made in order to solve the above-described problems. An optical waveguide capable of monolithically integrating a silica-based optical waveguide element and a silicon optical waveguide element and connecting these elements with low loss. The purpose is to provide a device.

  The optical waveguide device of the present invention includes an optical functional element configured by a silica optical waveguide, an optical functional element configured by a silicon optical waveguide, an optical functional element configured by the silica optical waveguide, and the silicon optical waveguide. A spot size converter for connecting an optical functional element configured by: an optical functional element configured by the silica-based optical waveguide; an optical functional element configured by the silicon optical waveguide; and the spot size converter. These are monolithically integrated on the same substrate, and the core of the silica-based optical waveguide and the first overclad of the silicon optical waveguide are made of the same layer film on the substrate.

In one configuration example of the optical waveguide device of the present invention, the silica-based optical waveguide includes an underclad formed on the substrate, a core formed on the underclad, and an overclad covering the core. The silicon optical waveguide includes an underclad formed on the substrate, a core made of silicon formed on the underclad, a first overclad covering the core, and the first The spot size converter includes an underclad formed on the substrate, and a width gradually increasing toward the silica-based optical waveguide on the underclad. A first core made of silicon formed to be thin; a second core covering the first core; and The under-clad of the silica-based optical waveguide, the under-clad of the silicon optical waveguide, and the under-clad of the spot size converter are formed of the same layer, and the silicon optical waveguide And the first core of the spot size converter are made of the same layer film, the core of the silica-based optical waveguide, the first overclad of the silicon optical waveguide, and the second of the spot size converter. The core of the same is made of a film of the same layer, and the over clad of the silica-based optical waveguide, the second over clad of the silicon optical waveguide, and the over clad of the spot size converter are made of the same layer of film. It is characterized by.
Moreover, in one configuration example of the optical waveguide device of the present invention, the silicon optical waveguide is a silicon fine wire optical waveguide having a core dimension of submicron order.

  According to the present invention, a spot size converter for connecting an output of an arrayed waveguide diffraction grating made of a silica-based optical waveguide and an input of a variable optical attenuator made of a silicon optical waveguide, the arrayed waveguide diffraction grating and the variable optical attenuation The silica-based optical waveguide device and the silicon optical waveguide device are provided on the same substrate as the container, and the core of the silica-based optical waveguide and the first overcladding of the silicon optical waveguide are formed of the same layer film on the substrate. Can be monolithically integrated, and these elements can be connected with low loss.

  In the present invention, the silicon optical waveguide is a silicon fine-wire optical waveguide having a core dimension of submicron order. In silicon optical waveguides, silicon cores have a higher refractive index than silica-based materials, and silicon thin-line optical waveguides that confine light in a small core with a submicron-order cross-sectional shape and propagate the light. By using it, it is possible to realize high speed and low power consumption by downsizing the element.

It is explanatory drawing which shows the structure of the monolithic integrated optical waveguide device which concerns on embodiment of this invention. It is an enlarged view of the spot size converter of the monolithic integrated optical waveguide device which concerns on embodiment of this invention. It is sectional drawing of the spot size converter of the monolithic integrated optical waveguide device which concerns on embodiment of this invention. It is sectional drawing of the silicon | silicone thin wire | line optical waveguide of the monolithic integrated optical waveguide device which concerns on embodiment of this invention. It is sectional drawing of the silica-type optical waveguide of the monolithic integrated optical waveguide device which concerns on embodiment of this invention. 1 is a plan view of a monolithic integrated optical waveguide device according to an embodiment of the present invention. It is a figure which shows the spectrum of the optical signal which passes the monolithic integrated optical waveguide device which concerns on embodiment of this invention. It is a figure which shows the response speed of the carrier injection type | mold variable optical attenuator of the monolithic integrated optical waveguide device which concerns on embodiment of this invention.

Embodiments according to the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory view showing the structure of a monolithic integrated optical waveguide device according to this embodiment.
The optical waveguide device of the present embodiment is a monolithically integrated silicon thin-wire optical waveguide element and a silica-based optical waveguide element on the same substrate, and a spot size converter (SSC) 101 that performs mode field size conversion; Carrier-injection variable optical attenuator (VOA), which is an optical functional element composed of a silicon fine wire optical waveguide 102 having a core dimension of the order of submicron, and an arrayed waveguide diffraction grating (optical functional element composed of a silica-based optical waveguide 103) AWG). In FIG. 1, the insides of the SSC 101 and the silicon fine wire optical waveguide 102 are seen through in order to make the structure easy to see.

FIG. 2 is an enlarged view of the SSC 101 that connects the silicon thin wire optical waveguide 102 and the silica-based optical waveguide 103. FIG. 3 is a cross-sectional view of the SSC 101 taken along the plane AA ′ in FIG. 2 and shows a cross-sectional structure of the SSC 101. The SSC 101 includes an underclad 201 made of silicon oxide (SiO ₂ ) formed on a silicon (Si) substrate 200 and silicon (Si) formed in a taper shape in a longitudinal direction (a direction perpendicular to the paper surface of FIG. 3). The core 202 includes a silica-based optical waveguide core 203 made of silicon oxide (SiO _x ) that covers the silicon core 202, and a silicon oxide (SiO ₂ ) film 204 that covers the silica-based optical waveguide core 203. The structure and function of the SSC 101 are disclosed in, for example, Japanese Patent Application Laid-Open No. 2004-184986.

FIG. 4 is a cross-sectional view of the silicon fine wire optical waveguide 102 taken along the plane BB ′ of FIG. 2 and shows a cross-sectional structure of the silicon fine wire optical waveguide 102. The silicon thin wire optical waveguide 102 includes an underclad 301 made of silicon oxide (SiO ₂ ) formed on a silicon substrate 200, a silicon core 302 formed on the underclad 301, and silicon oxide (SiO ₂ ) covering the silicon core 302. _x ) a film 303 and a silicon oxide (SiO ₂ ) film 304 covering the silicon oxide film 303.

FIG. 5 is a cross-sectional view of the silica-based optical waveguide 103 taken along the line CC ′ of FIG. 2, and shows a cross-sectional structure of the silica-based optical waveguide 103. The quartz optical waveguide 103 includes an underclad 401 made of silicon oxide (SiO ₂ ) formed on the silicon substrate 200 and a quartz optical waveguide core 403 made of silicon oxide (SiO _x ) formed on the underclad 401. And a silicon oxide (SiO ₂ ) film 404 covering the quartz optical waveguide core 403.

Here, the layers constituting the cross section shown in FIGS. 3, 4 and 5 are made common as follows, and thus monolithic integration can be achieved.
That is, the underclad 201 of the SSC 101 is in the same layer as the underclad 301 of the silicon fine wire optical waveguide 102 and the underclad 401 of the silica-based optical waveguide 103.

  The silicon core 202 of the SSC 101 is the same layer as the silicon core 302 of the silicon fine wire optical waveguide 102. As shown in FIG. 2, the silicon core 202 is formed in a tapered shape in the SSC 101 so that the width (dimension in the left-right direction in FIG. 3) gradually decreases in the direction of the silica-based optical waveguide 103. The silicon core 202 is not formed in the quartz optical waveguide 103. That is, the quartz optical waveguide 103 has a structure without a silicon layer as shown in FIG.

  The silica-based optical waveguide core 203 of the SSC 101 is the same layer as the silicon oxide film 303 of the silicon fine-wire optical waveguide 102 and the silica-based optical waveguide core 403 of the silica-based optical waveguide 103. In the SSC 101 and the silica-based optical waveguide 103, the width (dimension in the left-right direction in FIGS. 3 and 5) is defined so that the silica-based optical waveguide core 203 and the silica-based optical waveguide core 403 function as cores. On the other hand, in the silicon fine wire optical waveguide 102, the width of the silicon oxide film 303 is not defined. That is, the silicon oxide film 303 is formed so as to function as an overclad of the silicon fine wire optical waveguide 102.

  The silicon oxide film 204 of the SSC 101 is the same layer as the silicon oxide film 304 of the silicon fine wire optical waveguide 102 and the silicon oxide film 404 of the silica-based optical waveguide 103. That is, the silicon oxide films 204, 304, and 404 are all formed so as to function as an overcladding of each optical waveguide element.

An example of the dimension and refractive index of each component is shown below. The underclads 201, 301, and 401 formed on the silicon substrate 200 have a thickness of 3 μm and a refractive index of 1.45.
The silicon core 202 of the SSC 101 and the silicon core 302 of the silicon fine wire optical waveguide 102 have a refractive index of 3.48 and a thickness of 200 nm. The width of the silicon core 302 is 400 nm. On the other hand, the width of the silicon core 202 is 400 nm, which is the same as that of the silicon core 302, at the boundary between the silicon thin-line optical waveguide 102 and the SSC 101, but becomes narrower as it approaches the silica-based optical waveguide 103, and is 80 nm at the end of the taper. It has become.

The silica-based optical waveguide core 203 of the SSC 101, the silicon oxide film 303 of the silicon thin-line optical waveguide 102, and the silica-based optical waveguide core 403 of the silica-based optical waveguide 103 have a refractive index of 1.50 and a thickness of 3 μm. The width of the quartz optical waveguide cores 203 and 403 is 3 μm.
The silicon oxide film 204 of the SSC 101, the silicon oxide film 304 of the silicon thin wire optical waveguide 102, and the silicon oxide film 404 of the silica-based optical waveguide 103 all have a thickness of 5 μm and a refractive index of 1.47.

The material of the silicon core 202 of the SSC 101 and the silicon core 302 of the silicon thin wire optical waveguide 102 may be amorphous silicon, polysilicon, or the like.
In the present embodiment, the silica-based optical waveguide core 203 of the SSC 101, the silicon oxide film 303 of the silicon thin-line optical waveguide 102, and the silica-based optical waveguide core 403 of the silica-based optical waveguide 103 are made of silicon oxide (SiO _x However, silicon oxynitride (SiON) or polyimide whose refractive index is adjusted may be used. However, it is desirable that the shape and the refractive index are adjusted so that the silicon fine wire optical waveguide 102 and the silica-based optical waveguide 103 satisfy the single mode condition.

  The ECR plasma can generate a plasma in which the source gas is sufficiently dissociated under a low pressure, and a good film precursor can be obtained for controlling the refractive index. Further, unlike the capacitively coupled plasma, there is no problem that the temperature rises by increasing the amount of input power in order to sufficiently dissociate the gas. Thus, a high quality film for an optical waveguide can be obtained by the ECR plasma CVD method.

  FIG. 6 shows a plan view of the monolithic integrated optical waveguide device of the present embodiment. In FIG. 6, 501a and 501b are the same as the SSC 101 of FIG. Reference numeral 502 denotes a carrier injection variable optical attenuator (VOA) manufactured using the silicon fine wire optical waveguide 102, and reference numeral 503 denotes an arrayed waveguide diffraction grating (AWG) manufactured using the silica-based optical waveguide 103. Further, the region indicated by 504 is constituted by the silicon fine wire optical waveguide 102, and the region indicated by 505 is constituted by the silica-based optical waveguide 103.

  The optical signal input to the AWG 503 is demultiplexed into 16 channels at intervals of 200 GHz. The SSC 501a is provided for 16 channels. Each outlet port of the AWG 503 is connected to a silicon fine wire optical waveguide constituting the VOA 502 via the SSC 501a of the corresponding channel. Thereby, the optical signal demultiplexed by the AWG 503 and output from each output port is input to the input port of the corresponding channel of the VOA 502. At this time, the mode field diameter of the waveguide is reduced by the SSC 501a.

  The VOA 502 is provided for 16 channels, and the intensity adjustment of the optical signal of each channel can be performed independently for each channel. Similar to the SSC 501a, the SSC 501b is provided for 16 channels. Each output port of the VOA 502 is connected to a silica-based optical waveguide (not shown) via the SSC 501b of the corresponding channel. At this time, the mode field diameter of the waveguide is expanded by the SSC 501b. The silica-based optical waveguide of each channel is coupled to an optical fiber outside the device. In this way, an output signal is obtained. The structure and function of AWG are disclosed in Non-Patent Document 1, and the structure and function of VOA are disclosed in Non-Patent Document 2.

  The outline of the manufacturing process of the monolithic integrated optical waveguide device of the present embodiment is as follows. First, a silicon-on-insulator (SOI) substrate including a silicon substrate, an insulating layer formed on the silicon substrate, and an upper silicon layer formed on the insulating layer is prepared. It goes without saying that the insulating layer of this SOI substrate becomes the underclad 201, 301, 401 of FIGS.

  Next, the upper silicon layer of the SOI substrate is selectively removed by lithography and etching to form the silicon core 202 of the SSCs 501a and 501b and the silicon core 302 of the VOA 502. Further, ion implantation and electrode fabrication are performed to fabricate the VOA 502. To do.

  Next, the upper silicon layer of the SOI substrate is removed in a region where an optical functional element (here, AWG) using a quartz optical waveguide is manufactured. This enables monolithic integration of the silicon optical waveguide functional element and the silica-based optical waveguide functional element on the same substrate.

Subsequently, a silicon oxide (SiO _x ) film serving as a core of the AWG 503 (quartz optical waveguide 103) is deposited on the insulating layer (underclad 401) of the SOI substrate by ECR plasma CVD. Then, the silicon oxide film is selectively removed by photolithography and etching, and the quartz optical waveguide core 403 of the AWG 503 is manufactured.
Finally, silicon oxide (SiO ₂ ) films 204, 304, and 404 to be overclad are deposited.

  FIG. 7 is a diagram showing a spectrum of an optical signal passing through the monolithic integrated optical waveguide device of the present embodiment. As can be seen from FIG. 7, the optical level of the optical signal demultiplexed into each channel by the AWG 503 can be controlled for each channel by the VOA 502.

FIG. 8 shows the response speed of the VOA 502. Here, the bias voltage applied to the electrode of the VOA 502 is 0V. As is clear from FIG. 8, the response speed of the VOA 502 is 15 ns, and by monolithically integrating the AWG 503 and the VOA 502, a high-speed level control operation that cannot be realized with a VOA composed of a silica-based optical waveguide becomes possible.
As described above, according to the present embodiment, the integration of the silica-based optical waveguide device and the silicon fine-wire optical waveguide device is possible, so that a high-performance optical device can be realized.

  The present invention can be applied to a technique for monolithically integrating a silica-based optical waveguide element and a silicon optical waveguide element.

  101, 501a, 501b ... spot size converter, 102 ... silicon fine wire optical waveguide, 103 ... quartz optical waveguide, 200 ... silicon substrate, 201, 301, 401 ... underclad, 202, 302 ... silicon core, 203, 403 ... Quartz-based optical waveguide core, 204, 303, 304, 404 ... silicon oxide film, 502 ... carrier injection type variable optical attenuator, 503 ... array waveguide diffraction grating.

Claims (3)

An optical functional element composed of a silica-based optical waveguide;
An optical functional element constituted by a silicon optical waveguide;
An optical functional element constituted by the silica-based optical waveguide and a spot size converter for connecting the optical functional element constituted by the silicon optical waveguide;
The optical functional element constituted by the quartz optical waveguide, the optical functional element constituted by the silicon optical waveguide, and the spot size converter are monolithically integrated on the same substrate,
The core of the silica-based optical waveguide and the first overclad of the silicon optical waveguide are made of the same layer film on the substrate. The optical waveguide device according to claim 1, wherein
The silica-based optical waveguide is composed of an underclad formed on the substrate, a core formed on the underclad, and an overclad covering the core.
The silicon optical waveguide covers an underclad formed on the substrate, a core made of silicon formed on the underclad, a first overclad covering the core, and the first overclad. A second over clad,
The spot size converter includes a first core made of an underclad formed on the substrate, and a silicon formed on the underclad so that the width gradually decreases toward the quartz optical waveguide. And a second core that covers the first core, and an overcladding that covers the second core,
The under clad of the silica-based optical waveguide, the under clad of the silicon optical waveguide, and the under clad of the spot size converter are made of the same layer film,
The core of the silicon optical waveguide and the first core of the spot size converter are made of the same layer film,
The core of the silica-based optical waveguide, the first overclad of the silicon optical waveguide, and the second core of the spot size converter are made of the same layer film,
The optical waveguide device, wherein the overclad of the silica-based optical waveguide, the second overclad of the silicon optical waveguide, and the overclad of the spot size converter are made of the same layer. The optical waveguide device according to claim 1 or 2,
2. The optical waveguide device according to claim 1, wherein the silicon optical waveguide is a silicon fine wire optical waveguide having a core dimension of submicron order.