초록 ▼

In the optical gas sensor of the application, a three-dimensional reaction chamber structure is used to replace the traditional simple structure, so that the performance of the gas sensor can be enhanced in a wafer-level size. Besides, a light source, a reaction chamber and a light detector are inte

In the optical gas sensor of the application, a three-dimensional reaction chamber structure is used to replace the traditional simple structure, so that the performance of the gas sensor can be enhanced in a wafer-level size. Besides, a light source, a reaction chamber and a light detector are integrated into one wafer in an exemplary embodiment, so as to achieve the wafer-level integration. In addition, the optical gas sensor can detect various gases simultaneously and has wide application in fields such as home environment monitoring, industrial safety, and disease diagnosis and treatment.

대표청구항 ▼

1. An optical gas sensor, comprising: a substrate;a light source, disposed in the substrate;at least one light detector, disposed in the substrate; andat least one reaction chamber structure, disposed in the substrate and connected between the light source and the light detector,wherein the distance

1. An optical gas sensor, comprising: a substrate;a light source, disposed in the substrate;at least one light detector, disposed in the substrate; andat least one reaction chamber structure, disposed in the substrate and connected between the light source and the light detector,wherein the distance from the light source to the light detector is d, and a shortest travel path of a light from the light source to the light detector through the reaction chamber structure is greater than d,wherein the at least one reaction chamber structure is composed of a first sub-substrate and a second sub-substrate, the first sub-substrate has a plurality of convex portions and concave portions disposed alternately, the second sub-substrate has a plurality of convex portions and concave portions disposed alternately, andwherein the convex portions of the first sub-substrate correspond to the concave portions of the second sub-substrate, and the concave portions of the first sub-substrate correspond to the convex portions of the second sub-substrate. 2. The optical gas sensor of claim 1, wherein the substrate comprises a silicon-on-insulator (SOI) substrate, a silicon substrate, a metal substrate, a plastic substrate or a combination thereof. 3. The optical gas sensor of claim 1, wherein a material of the first sub-substrate is the same as a material of the second sub-substrate. 4. The optical gas sensor of claim 1, wherein a material of the first sub-substrate is different from a material of the second sub-substrate. 5. The optical gas sensor of claim 1, wherein a reflective layer is coated on an inner wall of the reaction chamber structure. 6. The optical gas sensor of claim 1, further comprising a plurality of gas holes for gas in and out, the gas holes disposed in the substrate and in communication with the reaction chamber structure. 7. The optical gas sensor of claim 1, wherein the reaction chamber structure has a serpentine shape. 8. The optical gas sensor of claim 1, wherein the reaction chamber structure has a spiral shape. 9. The optical gas sensor of claim 1, wherein the optical gas sensor is a wafer-level gas optical gas sensor. 10. The optical gas sensor of claim 1, wherein a number of the at least one light detector is more than one, a number of the at least one reaction chamber structure is more than one, and each of the reaction chamber structures is located between the light source and the corresponding light detector. 11. The optical gas sensor of claim 10, wherein the reaction chamber structures are radially arranged from the light source as a center.