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Abstract

The goal of this technical note was to compare experimentally and via simulation of eight substrate-integrated hollow waveguide (iHWG) designs, and to predict promising future iHWG structures in lieu of experiments. The iHWGs differed in their geometry (i.e., inlet funnel cross-section and inner channel cross-section), as well as in their material properties (i.e., type of metal, polish of inner channel). Experimentally, calibration functions of isobutane as a model analyte were determined, and the analytical figures of merit, i.e., signal-to-noise ratio, limit of detection, were evaluated for each iHWG. Evaluation of the amount of radiation incident at the real-world and simulated detector revealed that experiment and simulation were in excellent agreement. While material and quality of the inner channel wall did not have a significant influence on the performance, the iHWG geometry profoundly affected the performance in terms of light throughput: Increasing the inlet funnel dimensions and the inner channel cross-section benefits light throughout, and thus, the analytical signal. Based on these results, simulations of not yet fabricated iHWGs were performed and promising new iHWG structures were suggested.

Keywords

Substrate-integrated hollow waveguide iHWG Fourier transform infrared spectroscopy FT-IR infrared sensors mid-infrared MIR raytracing simulations FRED optical engineering software FRED

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References

Griffiths

P.R.

de Haseth

J.A.

“Other Components of FT-IR Spectrometers”. Fourier Transform Infrared Spectrometry. Hoboken, NJ: John Wiley and Sons, Inc., 2007, pp. 143–160. .

Griffiths

P.R.

de Haseth

J.A.

“Conventional Transmission Spectrometry”. Fourier Transform Infrared Spectrometry. Hoboken, NJ: John Wiley and Sons, Inc., 2007, pp. 251–260.

Wilk

Chance Carter

Chrisp

, et al. “Substrate-Integrated Hollow Waveguides: A New Level of Integration in Mid-Infrared Gas Sensing”. Anal. Chem. 2013. 85(23): 11205–11210.

Azarraga

L.V.

“Gold Coating of Glass Tubes for Gas Chromatography/Fourier Transform Infrared Spectroscopy ‘Light-Pipe’ Gas Cells”. Appl. Spectrosc. 1980. 34(2): 224–225.

Tütüncü

Nägele

Fuchs

, et al. “iHWG-ICL: Methane Sensing with Substrate-Integrated Hollow Waveguides Directly Coupled to Interband Cascade Lasers”. ACS Sensors. 2016. 1(7): 847–851.

Kokoric

Wissel

P.A.

Wilk

, et al. “MuciPRECON: Multichannel Preconcentrators for Portable Mid-Infrared Hydrocarbon Gas Sensors”. Anal. Methods. 2016. 8(36): 6645–6650.

Seichter

Tütüncü

Hagemann

L.T.

, et al. “Online Monitoring of Carbon Dioxide and Oxygen in Exhaled Mouse Breath via Substrate-Integrated Hollow Waveguide Fourier-Transform Infrared-Luminescence Spectroscopy”. J. Breath Res. 2018. 12(3): 036018.

Da Silveira Petruci

J.F.

Tütüncü

Cardoso

A.A.

, et al. “Real-Time and Simultaneous Monitoring of NO, NO₂, and N₂O Using Substrate–Integrated Hollow Waveguides Coupled to a Compact Fourier Transform Infrared (FT-IR) Spectrometer”. Appl. Spectrosc. 2018. 73(1): 98–103.

Fortes

P.R.

Flávio

Wilk

, et al. “Optimized Design of Substrate-Integrated Hollow Waveguides for Mid-Infrared Gas Analyzers”. J. Opt. 2014. 16(9): 094006.

10.

Tütüncü

Nägele

Becker

, et al. “Advanced Photonic Sensors Based on Interband Cascade Lasers for Real-Time Mouse Breath Analysis”. ACS Sensors. 2018. 3(9): 1743–1749.

11.

Ribessi

R.L.

Neves

T.D.A.

Rohwedder

J.J.R.

, et al. “iHEART: A Miniaturized Near-Infrared In-Line Gas Sensor Using Heart-Shaped Substrate-Integrated Hollow Waveguides”. Analyst. 2016. 141(18): 5298–5303.

12.

Hagemann

L.T.

McCartney

M.M.

Fung

A.G.

, et al. “Portable Combination of Fourier Transform Infrared Spectroscopy and Differential Mobility Spectrometry for Advanced Vapor Phase Analysis”. Analyst. 2018. 143(23): 5683–5691.

13.

Kokoric

Theisen

Wilk

, et al. “Determining the Partial Pressure of Volatile Components via Substrate-Integrated Hollow Waveguide Infrared Spectroscopy with Integrated Microfluidics”. Anal. Chem. 2018. 90(7): 4445–4451.

14.

Tütüncü

Kokoric

Szedlak

, et al. “Advanced Gas Sensors Based on Substrate-Integrated Hollow Waveguides and Dual-Color Ring Quantum Cascade Lasers”. Analyst. 2016. 141(22): 6202–6207.

15.

Stach

Haas

Tütüncü

, et al. “PolyHWG: 3D Printed Substrate-Integrated Hollow Waveguides for Mid-Infrared Gas Sensing”. ACS Sensors. 2017. 2(11): 1700–1705.

16.

Rohwedder

J.J.R.

Pasquini

Fortes

P.R.

, et al. “iHWG-μNIR: A Miniaturised Near-Infrared Gas Sensor Based on Substrate-Integrated Hollow Waveguides Coupled to a Micro-NIR Spectrophotometer”. Analyst. 2014. 139(14): 3572–3576.

17.

Kokoric

Widmann

Wittmann

, et al. “Infrared Spectroscopy via Substrate-Integrated Hollow Waveguides: A Powerful Tool in Catalysis”. Analyst. 2016. 141(21): 5990–5995.

18.

Perez-Guaita

Kokoric

Wilk

, et al. “Towards the Determination of Isoprene in Human Breath Using Substrate-Integrated Hollow Waveguide Mid-Infrared Sensors”. J. Breath Res. 2014. 8(2): 026003.

19.

Da Silveira Petruci

J.F.

Fortes

P.R.

Kokoric

, et al. “Monitoring of Hydrogen Sulfide via Substrate-Integrated Hollow Waveguide Mid-Infrared Sensors in Real-Time”. Analyst. 2014. 139(1): 198–203.

20.

Da Silveira Petruci

J.F.

Wilk

Cardoso

A.A.

, et al. “Online Analysis of H₂S and SO₂ via Advanced Mid-Infrared Gas Sensors”. Anal. Chem. 2015. 87(19): 9605–9611.

21.

Helfert

S.F.

Seiler

Jahns

, et al. “Numerical Simulation of Hollow Waveguide Arrays as Polarization Converting Elements and Experimental Verification”. Opt. Quantum Electron. 2017. 49(9): 313.

22.

Gerhard

Beigang

Rahm

“Comparative Terahertz Study of Rectangular Metal Waveguides with and without a Ridge”. J. Infrared Millimeter Terahertz Waves. 2015. 36(4): 327–334.

23.

Nakahama

Ahmed

, et al. “Beam-Steering in Hollow ZrO₂/SiO₂ Distributed Bragg Reflector Waveguides for One-Dimensional RGB Imaging”. Jpn. J. Appl. Phys. 2014. 53(3): 030302.

24.

Hunsperger

R.G.

“Optical Waveguide Modes”. Integrated Optics: Theory and Technology. New York: Springer Science and Business Media, 2009, pp. 17–31.

25.

Salinas

Garcés

Alonso

, et al. “Simple Estimation of Transition Losses in Bends of Wide Optical Waveguides by a Ray Tracing Method”. IEEE Photonics Technol. Lett. 2004. 16(3): 825–827.

26.

Wilk

Kim

S.S.

Mizaikoff

“An Approach to the Spectral Simulation of Infrared Hollow Waveguide Gas Sensors”. Anal. Bioanal. Chem. 2009. 395(6): 1661–1671.

27.

Izquierdo

Salinas

Cadarso

, et al. “Hollow Waveguides Ray-Tracing Analysis”. Proc. SPIE. 2008. 6992: 699216.

28.

Bledt

C.M.

Melzer

J.E.

Harrington

J.A.

“Theoretical and Experimental Investigation of Infrared Properties of Tapered Silver/Silver Halide-Coated Hollow Waveguides”. Appl. Opt. 2013. 52(16): 3703.

29.

Darafsheh

Fardad

Fried

N.M.

, et al. “Contact Focusing Multimodal Microprobes for Ultraprecise Laser Tissue Surgery”. Opt. Express. 2011. 19(4): 3440.

30.

J. Inczédy, T. Lengyel “Performance Characteristics of the Measurement Process”. In: (Eds) J. Inczédy, T. Lengyel, A. M. Ure. Compendium of Analytical Nomenclature Definitive Rules 1997. Oxford, U.K.: Blackwell Science, 1997. Chap. 18.4.3., pp. 18.23–18.44.

31.

Thorlabs. “MPD254254-90-M01 – Ø1” 90° Off-Axis Parabolic Mirror, Prot. Gold, RFL = 2”. https://www.thorlabs.com/thorproduct.cfm?partnumber=MPD254254-90-M01 [accessed Aug 17 2018].

32.

Rakić

A.D.

“Algorithm for the Determination of Intrinsic Optical Constants of Metal Films: Application to Aluminum”. Appl. Opt. 1995. 34(22): 4755–4767.

33.

Hagemann

H.-J.

Gudat

Kunz

“Optical Constants from the Far Infrared to the X-ray Region: Mg, Al, Cu, Ag, Au, Bi, C, and Al₂O₃”. J. Opt. Soc. Am. 1975. 65(6): 742–744.

34.

H.-J. Hagemann

C.K.

Gudat

Optical Constants from the Far Infrared to the X-ray Region: Mg, Al, Cu, Ag, Au, Bi, C, and Al₂O₃. Hamberg, Germany: Deutsches Elektronen-Synchroton DESY, 1974.

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Optimizing the Analytical Performance of Substrate-Integrated Hollow Waveguides: Experiment and Simulation

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