SE1350785A1 - Optical waveguide gas sensor - Google Patents

Abstract

Abstract An open hollow core optical waveguide (100, 200) for a gas sensorcomprising: an outer tubular element (102) having a sidewall, comprising anelongated opening (104) in the sidewall extending in the longitudinal directionalong the length of a portion of the tubular element; a transparent inner hollowlight guiding structure (106) forming a light guiding core, attached to an innerwall of the outer tubular element, the inner hollow light guiding structurecomprising an elongated opening (108), arranged such that the light guidingcore is in fluid communication with the elongated opening of the outer tubular element. Fig. 2

Description

OPTICAL WAVEGUIDE GAS SENSOR Field of the lnventionThe present invention relates to an optical waveguide. ln particular, thepresent invention relates to a hollow core optical waveguide suitable for use in an environmental sensor.

Technical BackgroundOptical fibers are capable of guiding light for long distances and can therefore be used as distributed sensors. Even in shorter distances (metersrange), optical fibers find applications in which the light beam does not spreadin space.

Develpments in the field of fiber optics has led to development ofhollow core fibers, where light is guided primarily in the hollow of a fiber, andthe glass structure around the hollow core only guarantees that light does notescape transversally. Even wavelengths that would normally be absorbed bysilica can be guided in this way. Capillaries coated with metal on the insideand fibers with a periodic distribution of longitudinally arranged holes, so-called photonic bandgap fibers, have been used to guide light in the hollowcore. lf water vapor or gas is inserted in the core, light can detect its presenceby the characteristic absorption lines. Such a sensor is effective as all of theoptical field interacts with the gas, and not just the evanescent field.

There are applications where it is desirable to measure, in a distributedway, the presence of gases or liquids. Two examples are given in thefollowing. First, in a refinery it may be crucial to be able to detect in variouslocations the presence of a gas that may be leaking. Secondly, it can beadvantageous to be able to detect the presence of water vapor, for exampleinside a bathroom wall, which would indicate water leakage. ln bothexamples, the wavelength region of interest is the mid-infrared, where mostgas absorption lines are located (3-5 um), and where water has its main peak(2.8 um). Note that the cut-off of silica is at around 2 um.

Optical fibers having a hollow core are known in the art. Such hollowcores typically guides light by way of a photonic bandgap structure (PBG)arranged within the fiber.

One example of an optical waveguide environmental sensor can befound in US 7,343,074 which disclose a waveguide in the form of an opticalfiber, where the cladding contains a photonic bandgap structure having alattice-type microstructure enveloping a light conducting hollow core portion.The cladding further includes at least one elongated side opening so that thehollow core portion is exposed to the ambient environment.

However, in order to form the elongated opening, the cladding must bechemically etched or laser machined. Such a process is both complicated andtime consuming, thereby increasing the cost of manufacturing the sensor. Theprocess of forming the opening may furthermore damage or disrupt thephotonic bandgap structure in an uncontrolled manner such that theperformance of the light guide is degraded.

Summarv of the lnvention ln view of the above-mentioned and other drawbacks of the prior art, ageneral object of the present invention is to provide an improved device foruse as an optical waveguide environmental sensor.

According to a first aspect of the present invention, it is thereforeprovided an open hollow core optical waveguide for a gas sensor comprising:an outer tubular element having a sidewall, comprising an elongated openingin said sidewall extending in the longitudinal direction along the length of aportion of said tubular element; a transparent inner hollow light guidingstructure forming a light guiding core, attached to an inner wall of the outertubular element, the inner hollow light guiding structure comprising anelongated opening, arranged such that the light guiding core is in fluidcommunication with the elongated opening of the outer tubular element.

The hollow core optical waveguide can be understood as an opticalfiber having a hollow core, and an additional structure within the hollow core forming a confinement region for light propagating in the core. Through theopenings in the inner element and the outer element, the environment outsideof the optical waveguide can come into contact with the light guiding core.Thereby, a change in environment can be detected by analyzing the spectraof light having passed through the waveguide, and the waveguide can thus beused in a gas or fluid sensor. Even though the open hollow core opticalwaveguide is discussed in reference to its use in a gas sensor, it mayobviously equally well be used in a fluid sensor. The hollow core may forexample be filled by water or other fluids, thereby making it possible toanalyze the fluid by studying the properties of light having propagated througha specific fluid.

Accordingly, an advantage of the present invention is that an opticalfiber design allowing free communication between the hollow light guidingcore and the outside environment without additional disturbance of theguidance of light is provided.

A further advantage of a hollow core waveguide according to variousembodiments of the invention is that it may advantageously be used in asensor in a hydrocarbon rich environment, where a conventional optical fibermay darken due to the creation of OH radicals. This will not be the case hereas light is guided in an air-core.

Both the outer tubular element and the inner light guiding structure mayadvantageously be made from materials used in conventional optical fibers,such as silica. ln one embodiment of the invention, the inner hollow light guidingstructure may comprise a tubular structure fixedly attached to the sidewall ofthe outer tubular element at a plurality of separate locations spaced apartfrom each other. One way to achieve a light guiding hollow core is to providea second tubular structure within the outer tubular structure, and attaching theinner structure to the outer at specific locations, so that the distance between the two tubular structures is fixed.

According to one embodiment of the invention, the inner hollow lightguiding structure may comprises a plurality of elongate elements arrangedadjacent to each other, extending Iongitudinally along the length of a portionof the outer tubular element, and wherein at least two of the elongateelements are arranged at a distance from each other to form the opening ofthe inner hollow light guiding structure. A light guiding core may be providedthrough a plurality of tubular elongate element arranged adjacent to eachother to form a confining circle within the outer tubular element. ln the samemanner as described above, destructive and constructive interferencedetermined by the dimension of the elongate elements determines whichwavelengths may propagate in the light guiding core. Furthermore, byarranging at least two of the elements at a distance from each other in thecircumferential direction, an opening is formed, an by aligning the openingwith the opening in the outer tubular element, the environment outside of theoptical waveguide can reach the core. ln one embodiment of the invention, a distance from an inner wall ofthe inner hollow light guiding structure to an inner wall of outer tubularelement may advantageously be selected such that only light of selectedwavelengths may propagate in said waveguide. lnterference between theinner wall of the outer tubular structure and the opposite wall of the innerhollow light guiding structure gives specific allowed wavelengths/modes dueto destructive/constructive interference. Thus, the allowable wavelengthswithin the optical waveguide can be selected by selecting the distancebetween the outer tubular structure and the inner hollow light guidingstructure.

Brief Description of the DrawinqsThese and other aspects of the present invention will now be describedin more detail with reference to the appended drawings showing an example embodiment of the invention, wherein: Fig. 1 schematically illustrates a waveguide according to anembodiment of the invention; Figs. 2a-b schematically illustrates a waveguide according to anembodiment of the invention; and Fig. 3 schematically illustrates a waveguide according to an embodiment of the invention.

Detailed Description of Preferred Embodiments of the lnvention Figs. 1a-b illustrates examples an open hollow core optical waveguide100 for a gas sensor comprising an outer tubular element 102 having asidewall, comprising an elongated opening 104 in said sidewall extending inthe longitudinal direction along the length of a portion of said tubular element;a transparent inner hollow light guiding structure 106 forming a light guidingcore, attached to an inner wall of said outer tubular element, said inner hollowlight guiding structure comprising an elongated opening 108, arranged suchthat the light guiding core is in fluid communication with the elongatedopening of said outer tubular element.

Typical dimensions are: outer diameter 125 um. lnner core 60 um.Openings 1 um. The openings do not need to be aligned. Thickness: outerstructure: 25 um. lnner: 1 um.

Fig. 2 and Fig. 3 shows an open hollow core optical waveguide 200,300 for a gas sensor wherein the inner hollow light guiding structurecomprises tubular structures 202, 302 fixedly attached to the sidewall of theouter tubular element at a plurality of separate locations. ln Fig. 3, the tubularstructures 302 are spaced apart from each other.

Claims (8)

1. An open hollow core optical waveguide (100, 200) for a gassensor comprising: an outer tubular element (102) having a sidewall, comprising anelongated opening (104) in said sidewall extending in the Iongitudinaldirection along the length of a portion of said tubular element; a transparent inner hollow light guiding structure (106) forming a lightguiding core, attached to an inner wall of said outer tubular element, saidinner hollow light guiding structure comprising an elongated opening (108),arranged such that said light guiding core is in fluid communication with saidelongated opening of said outer tubular element.

2. The optical waveguide according to claim 1, wherein said innerhollow light guiding structure comprises a tubular structure (202, 302) fixedlyattached to said sidewall of said outer tubular element at a plurality of separate locations spaced apart from each other.

3. The optical waveguide according to claim 1, wherein said innerhollow light guiding structure comprises a plurality of elongate elementsarranged adjacent to each other, extending longitudinally along the length of aportion of said outer tubular element, and wherein at least two of saidelongate elements are arranged at a distance from each other to form saidopening of said inner hollow light guiding structure.

4. The optical waveguide according to claim 3, wherein said elongate element is a hollow circular element.

5. The optical waveguide according to any one of the preceding claims, wherein said outer tubular element is a circular element.

6. The optical waveguide according to any one of the precedingclaims, wherein a distance from an inner wall of said inner hollow light guidingstructure to an inner wall of outer tubular element is selected such that onlylight of selected wavelengths may propagate in said waveguide.

7. The optical waveguide according to any one of the preceding claims,in a first end optically coupled to a first optical fiber and in a second endoptically coupled to a second optical fiber.

8. A gas sensor comprising: a light source configured to couple light into an optical waveguideaccording to any one of the preceding claims; and an optical receiver configured to receive light having passed throughsaid optical waveguide; and a spectrum analyzer configured to analyze said received light. 10. Method for manufacturing an optical waveguide gas sensor, saidmethod comprising the steps of:forming a perform comprising a tubular cladding;forming an elongated opening along a portion of the length of saidtubular cladding;arranging a hollow light guiding structure within said tubular cladding;drawing an optical fiber from said perform.