A sulfide-silicon nitride suspended waveguide capable of forward Brillouin scattering and its preparation method

A technology of Brillouin scattering and suspended waveguide, which is applied in the direction of optical waveguide, light guide, instrument, etc., can solve the problems of difficult suspended structure, soft vulcanized material, limiting device gain and performance, etc.

Active Publication Date: 2021-04-02
SUN YAT SEN UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0003] At present, the material system based on on-chip forward Brillouin scattering is mainly silicon-based. By suspending the waveguide, the simultaneous localization of sound and light can be realized in the subwavelength fiber core structure, but silicon has a strong two-photon near 1550 nanometers. Absorption and free carrier absorption and other characteristics, while parameters such as Brillouin frequency shift and line width are very sensitive to the size of silicon-based devices, and changes in nanometer size will have a great impact on it, which greatly limits Achievable gain and performance of the device, so it is necessary to find other material platforms that can be used to achieve Brillouin
Sulfides are widely used in the field of backward Brillouin integration due to their excellent acousto-optic quality factor and negligible two-photon absorption, but there are no reports on forward Brillouin integration.
The key to realizing forward Brillouin scattering lies in the limitation of lateral phonons. Generally, a suspended structure is required, but the sulfide material is soft, and it is difficult to prepare a suspended structure.

Method used

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  • A sulfide-silicon nitride suspended waveguide capable of forward Brillouin scattering and its preparation method
  • A sulfide-silicon nitride suspended waveguide capable of forward Brillouin scattering and its preparation method
  • A sulfide-silicon nitride suspended waveguide capable of forward Brillouin scattering and its preparation method

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Embodiment 1

[0027] Such as figure 1 It shows a sulfide-silicon nitride suspended waveguide that can realize forward Brillouin scattering. From bottom to top, there are silicon substrate 1, silicon oxide layer 2, silicon nitride film layer 3, and sulfide film layer 4. ; Both sides of the sulfide thin film layer 4 are etched with a ridge structure 7 of a chalcogenide waveguide; a first air groove 6 is also etched on the sulfide thin film layer 4, and the first air groove 6 is located at the ridge The two sides of the shaped structure 7; the silicon nitride thin film layer 3 and the sulfide thin film layer 4 are etched below the second air groove 5, and the first air groove 6 communicates with the second air groove 5.

[0028] Wherein, the thickness of the silicon substrate 1 is 525 microns or 700 microns. The thickness of the silicon oxide layer 2 is 2 microns-3 microns. The silicon nitride thin film layer 3 is located on the silicon oxide layer 2 and is grown by chemical vapor deposition...

Embodiment 2

[0030] The present invention also provides a method for preparing a sulfide-silicon nitride suspended waveguide capable of forward Brillouin scattering, such as figure 2 shown, including the following steps:

[0031] S1. On the silicon substrate 1 layer and the silicon oxide layer 2 substrate, a silicon nitride film layer 3 with a thickness of about 100-200 nanometers is grown by chemical vapor deposition;

[0032] S2. Evaporating a 300-500 nanometer sulfide film layer 4 on the silicon nitride film layer 3 by thermal evaporation;

[0033] S3. Etching the ridge structure 7 of the chalcogenide waveguide on the sulfide film layer 4 by using electron beam exposure and dry etching technology, wherein the etching depth of the ridge structure 7 of the chalcogenide waveguide is 200-400 nanometers, The width is 1-2 microns;

[0034] S4. Etching the remaining sulfide and silicon nitride thin film layers 3 on both sides of the ridge waveguide until the silicon oxide layer 2 in the mid...

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Abstract

The invention belongs to the technical field of semiconductor devices, and particularly relates to a sulfide-silicon nitride suspended waveguide design capable of realizing forward Brillouin scattering and a preparation method thereof. The sulfide-silicon nitride suspended waveguide sequentially comprises a silicon substrate, a silicon oxide layer, a silicon nitride thin film layer and a sulfide thin film layer from bottom to top, wherein the silicon oxide layer below the waveguide is partially corroded to form a suspended structure. The invention provides a sulfide-silicon nitride suspended waveguide structure capable of realizing forward Brillouin scattering. The introduction of the silicon nitride structure plays a role in supporting the chalcogenide film; defects of vulcanizate softening, hanging difficulty can be overcome, meanwhile, silicon nitride is compared with sulfide, the refractive index is small, the difference of acoustic sound velocity properties is large, simultaneouslimitation of a light field and a transverse sound field is facilitated, the forward Brillouin gain coefficient obtained through simulation is 1415 m <-1 > W <-1 >, and it is proved that the structurecan be used for achieving the possibility of forward stimulated Brillouin scattering, optical machinery and other applications.

Description

technical field [0001] The invention belongs to the technical field of semiconductors, and more specifically relates to a sulfide-silicon nitride suspended waveguide capable of realizing forward Brillouin scattering and a preparation method thereof. Background technique [0002] Stimulated Brillouin scattering is widely used in microwave photonic filters, microwave signal source generation, fast light and slow light, optical storage, narrow linewidth lasers, etc., but most of the previous studies were based on the traditional backward Brillouin Abyss scattering. With the development of on-chip integrated devices, Brillouin integrated photonics has attracted more and more attention. Brillouin integrated photonics expands the realization mechanism of Brillouin scattering, especially forward Brillouin. Compared with backscattering, this scattering mechanism participates in transverse phonons, which have been applied in distributed sensing, Brillouin lasers, cavity-enhanced am...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G02B6/12G02B6/122G02B6/132G02B6/136G10K11/28
CPCG02B6/12G02B6/122G02B6/132G02B6/136G02B2006/12035G02B2006/12061G02B2006/12097G10K11/28
Inventor 李朝晖宋景翠
Owner SUN YAT SEN UNIV
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