Sensitivity optimization of tapered optical fiber humidity sensors by means of tuning the thickness of nanostructured sensitive coatings

Jesús M. Corres; Francisco J. Arregui; Ignacio R. Matías

doi:10.1016/j.snb.2006.06.008

Sensitivity optimization of tapered optical fiber humidity sensors by means of tuning the thickness of nanostructured sensitive coatings

Jesús M. Corres^*
, Francisco J. Arregui
, Ignacio R. Matías

^*Corresponding author for this work

Public University of Navarre

Research output: Contribution to journal › Article › peer-review

125 Citations (Scopus)

Abstract

Electrostatic self-assembly has been used in this work to fabricate a new optical fiber humidity sensor. Said sensor consists of a single-mode tapered fiber coated with a [PDDA/Poly R-478] nanostructured overlay, in such a way that the thickness can be controlled in order to optimize the sensor sensitivity, by stopping the deposition process at the maximum slope of the transmitted optical power. The same tapered optical fiber tested with an overlay coating at the optimal working point achieves 26.8 times better sensitivity than with a double thickness overlay. A variation of 16 dB in optical power is achieved with responses time of 300 ms for changes in relative humidity from 75% to 100%. The high dynamic performance and low temperature cross-sensitivity allows this sensor to be used for human breathing monitoring.

Original language	English
Pages (from-to)	442-449
Number of pages	8
Journal	Sensors and Actuators B: Chemical
Volume	122
Issue number	2
DOIs	https://doi.org/10.1016/j.snb.2006.06.008
Publication status	Published - 26 Mar 2007
Externally published	Yes

Keywords

Fiber optic sensors
Humidity sensors
Ionic self-assembly monolayer
Tapered optical fibers

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10.1016/j.snb.2006.06.008

Cite this

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title = "Sensitivity optimization of tapered optical fiber humidity sensors by means of tuning the thickness of nanostructured sensitive coatings",

abstract = "Electrostatic self-assembly has been used in this work to fabricate a new optical fiber humidity sensor. Said sensor consists of a single-mode tapered fiber coated with a [PDDA/Poly R-478] nanostructured overlay, in such a way that the thickness can be controlled in order to optimize the sensor sensitivity, by stopping the deposition process at the maximum slope of the transmitted optical power. The same tapered optical fiber tested with an overlay coating at the optimal working point achieves 26.8 times better sensitivity than with a double thickness overlay. A variation of 16 dB in optical power is achieved with responses time of 300 ms for changes in relative humidity from 75\% to 100\%. The high dynamic performance and low temperature cross-sensitivity allows this sensor to be used for human breathing monitoring.",

keywords = "Fiber optic sensors, Humidity sensors, Ionic self-assembly monolayer, Tapered optical fibers",

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year = "2007",

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doi = "10.1016/j.snb.2006.06.008",

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AU - Corres, Jesús M.

AU - Arregui, Francisco J.

AU - Matías, Ignacio R.

PY - 2007/3/26

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N2 - Electrostatic self-assembly has been used in this work to fabricate a new optical fiber humidity sensor. Said sensor consists of a single-mode tapered fiber coated with a [PDDA/Poly R-478] nanostructured overlay, in such a way that the thickness can be controlled in order to optimize the sensor sensitivity, by stopping the deposition process at the maximum slope of the transmitted optical power. The same tapered optical fiber tested with an overlay coating at the optimal working point achieves 26.8 times better sensitivity than with a double thickness overlay. A variation of 16 dB in optical power is achieved with responses time of 300 ms for changes in relative humidity from 75% to 100%. The high dynamic performance and low temperature cross-sensitivity allows this sensor to be used for human breathing monitoring.

AB - Electrostatic self-assembly has been used in this work to fabricate a new optical fiber humidity sensor. Said sensor consists of a single-mode tapered fiber coated with a [PDDA/Poly R-478] nanostructured overlay, in such a way that the thickness can be controlled in order to optimize the sensor sensitivity, by stopping the deposition process at the maximum slope of the transmitted optical power. The same tapered optical fiber tested with an overlay coating at the optimal working point achieves 26.8 times better sensitivity than with a double thickness overlay. A variation of 16 dB in optical power is achieved with responses time of 300 ms for changes in relative humidity from 75% to 100%. The high dynamic performance and low temperature cross-sensitivity allows this sensor to be used for human breathing monitoring.

KW - Fiber optic sensors

KW - Humidity sensors

KW - Ionic self-assembly monolayer

KW - Tapered optical fibers

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JO - Sensors and Actuators B: Chemical

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ER -

Sensitivity optimization of tapered optical fiber humidity sensors by means of tuning the thickness of nanostructured sensitive coatings

Abstract

Keywords

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