Evanescent-Wave Gas Sensing Using an Integrated Thermal Light Source

Christina Cosani; Christian Ranacher; Andreas Tortschanoff; Thomas Grille; Peter Irsigler; Bernhard Jakoby

doi:10.3390/proceedings1040550

Evanescent-Wave Gas Sensing Using an Integrated Thermal Light Source

Christina Cosani, Christian Ranacher, Andreas Tortschanoff, Thomas Grille, Peter Irsigler, Bernhard Jakoby

Institute of Microelectronics and Microsensors

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

The last years showed an increased request for miniaturised, CMOS-compatible gas detectors. In contrast to sensors utilizing metal-oxide chemical interfaces, optical strategies are potentially faster and more robust. Recently we demonstrated CO2 detection by evanescent-wave absorption in the mid-infrared using a combination of an external laser source and silicon waveguides based on CMOS technology. We now go one step further and demonstrate the feasibility of detection of CO2 down to a concentration of 3% with a low-cost integrated thermal source. These results are promising for further technological developments towards on-chip mid-infrared photonic gas sensors, and new designs are currently devised to increase the yet relatively low sensitivity.

Original language	English
Title of host publication	Proceedings Eurosensors 2017
Pages	550
Number of pages	5
Volume	1
DOIs	https://doi.org/10.3390/proceedings1040550
Publication status	Published - 2017

Publication series

Name	mdpi Proceedings

Fields of science

202019 High frequency engineering
202021 Industrial electronics
202036 Sensor systems
203017 Micromechanics
202 Electrical Engineering, Electronics, Information Engineering
202027 Mechatronics
202028 Microelectronics
202037 Signal processing

JKU Focus areas

Mechatronics and Information Processing

Access to Document

10.3390/proceedings1040550

Cite this

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title = "Evanescent-Wave Gas Sensing Using an Integrated Thermal Light Source",

abstract = "The last years showed an increased request for miniaturised, CMOS-compatible gas detectors. In contrast to sensors utilizing metal-oxide chemical interfaces, optical strategies are potentially faster and more robust. Recently we demonstrated CO2 detection by evanescent-wave absorption in the mid-infrared using a combination of an external laser source and silicon waveguides based on CMOS technology. We now go one step further and demonstrate the feasibility of detection of CO2 down to a concentration of 3\% with a low-cost integrated thermal source. These results are promising for further technological developments towards on-chip mid-infrared photonic gas sensors, and new designs are currently devised to increase the yet relatively low sensitivity.",

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AU - Cosani, Christina

AU - Ranacher, Christian

AU - Tortschanoff, Andreas

AU - Grille, Thomas

AU - Irsigler, Peter

AU - Jakoby, Bernhard

PY - 2017

Y1 - 2017

N2 - The last years showed an increased request for miniaturised, CMOS-compatible gas detectors. In contrast to sensors utilizing metal-oxide chemical interfaces, optical strategies are potentially faster and more robust. Recently we demonstrated CO2 detection by evanescent-wave absorption in the mid-infrared using a combination of an external laser source and silicon waveguides based on CMOS technology. We now go one step further and demonstrate the feasibility of detection of CO2 down to a concentration of 3% with a low-cost integrated thermal source. These results are promising for further technological developments towards on-chip mid-infrared photonic gas sensors, and new designs are currently devised to increase the yet relatively low sensitivity.

AB - The last years showed an increased request for miniaturised, CMOS-compatible gas detectors. In contrast to sensors utilizing metal-oxide chemical interfaces, optical strategies are potentially faster and more robust. Recently we demonstrated CO2 detection by evanescent-wave absorption in the mid-infrared using a combination of an external laser source and silicon waveguides based on CMOS technology. We now go one step further and demonstrate the feasibility of detection of CO2 down to a concentration of 3% with a low-cost integrated thermal source. These results are promising for further technological developments towards on-chip mid-infrared photonic gas sensors, and new designs are currently devised to increase the yet relatively low sensitivity.

U2 - 10.3390/proceedings1040550

DO - 10.3390/proceedings1040550

M3 - Conference proceedings

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