A Fluorescence Intensity Ratiometric Fiber Optics–Based Chemical Sensor for Monitoring pH

Martin Rosenberg; Bo W. Laursen; Christian G. Frankær; Thomas Just Sørensen

doi:10.1002/admt.201800205

A Fluorescence Intensity Ratiometric Fiber Optics–Based Chemical Sensor for Monitoring pH

Martin Rosenberg, Bo W. Laursen, Christian G. Frankær, Thomas Just Sørensen

14 Citationer (Scopus)

Abstract

Accurate determination of pH is essential, yet a single technology is relied upon for almost all pH measurements. Here, a new optical pH sensor is described. Two highly photostable fluorescent dyes with a polymerizable side chain are incorporated into a composite polymer that allows for fast transport of protons. A pH-responsive dye and a reference dye with limited response to pH are used, thus allowing for determining pH using a ratiometric fluorescence intensity response. The sensor material—dyes covalently attached in the composite polymer—is deposited on a polycarbonate hemiwicking substrate, and immobilized on the inside of a shaker flask. In this manner, two robust pH optodes with pK_a values of 5.30 and 6.11 are prepared. The pH-responsive composite materials are addressed using fiber optics, and the response is recorded on a fiber spectrometer. The optodes are shown to have low drift, fast response time, no leachables, and the sensor is shown to work in heterogeneous media exemplified with coffee, beer, and cola.

Originalsprog	Engelsk
Artikelnummer	1800205
Tidsskrift	Advanced Materials Technologies
Vol/bind	3
Udgave nummer	12
Sider (fra-til)	1-5
Antal sider	5
ISSN	2365-709X
DOI	https://doi.org/10.1002/admt.201800205
Status	Udgivet - dec. 2018

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10.1002/admt.201800205

Citationsformater

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title = "A Fluorescence Intensity Ratiometric Fiber Optics–Based Chemical Sensor for Monitoring pH",

abstract = "Accurate determination of pH is essential, yet a single technology is relied upon for almost all pH measurements. Here, a new optical pH sensor is described. Two highly photostable fluorescent dyes with a polymerizable side chain are incorporated into a composite polymer that allows for fast transport of protons. A pH-responsive dye and a reference dye with limited response to pH are used, thus allowing for determining pH using a ratiometric fluorescence intensity response. The sensor material—dyes covalently attached in the composite polymer—is deposited on a polycarbonate hemiwicking substrate, and immobilized on the inside of a shaker flask. In this manner, two robust pH optodes with pKa values of 5.30 and 6.11 are prepared. The pH-responsive composite materials are addressed using fiber optics, and the response is recorded on a fiber spectrometer. The optodes are shown to have low drift, fast response time, no leachables, and the sensor is shown to work in heterogeneous media exemplified with coffee, beer, and cola.",

author = "Martin Rosenberg and Laursen, {Bo W.} and Frank{\ae}r, {Christian G.} and S{\o}rensen, {Thomas Just}",

year = "2018",

month = dec,

doi = "10.1002/admt.201800205",

language = "English",

volume = "3",

pages = "1--5",

journal = "Advanced Materials Technologies",

issn = "2365-709X",

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T1 - A Fluorescence Intensity Ratiometric Fiber Optics–Based Chemical Sensor for Monitoring pH

AU - Rosenberg, Martin

AU - Laursen, Bo W.

AU - Frankær, Christian G.

AU - Sørensen, Thomas Just

PY - 2018/12

Y1 - 2018/12

N2 - Accurate determination of pH is essential, yet a single technology is relied upon for almost all pH measurements. Here, a new optical pH sensor is described. Two highly photostable fluorescent dyes with a polymerizable side chain are incorporated into a composite polymer that allows for fast transport of protons. A pH-responsive dye and a reference dye with limited response to pH are used, thus allowing for determining pH using a ratiometric fluorescence intensity response. The sensor material—dyes covalently attached in the composite polymer—is deposited on a polycarbonate hemiwicking substrate, and immobilized on the inside of a shaker flask. In this manner, two robust pH optodes with pKa values of 5.30 and 6.11 are prepared. The pH-responsive composite materials are addressed using fiber optics, and the response is recorded on a fiber spectrometer. The optodes are shown to have low drift, fast response time, no leachables, and the sensor is shown to work in heterogeneous media exemplified with coffee, beer, and cola.

AB - Accurate determination of pH is essential, yet a single technology is relied upon for almost all pH measurements. Here, a new optical pH sensor is described. Two highly photostable fluorescent dyes with a polymerizable side chain are incorporated into a composite polymer that allows for fast transport of protons. A pH-responsive dye and a reference dye with limited response to pH are used, thus allowing for determining pH using a ratiometric fluorescence intensity response. The sensor material—dyes covalently attached in the composite polymer—is deposited on a polycarbonate hemiwicking substrate, and immobilized on the inside of a shaker flask. In this manner, two robust pH optodes with pKa values of 5.30 and 6.11 are prepared. The pH-responsive composite materials are addressed using fiber optics, and the response is recorded on a fiber spectrometer. The optodes are shown to have low drift, fast response time, no leachables, and the sensor is shown to work in heterogeneous media exemplified with coffee, beer, and cola.

U2 - 10.1002/admt.201800205

DO - 10.1002/admt.201800205

M3 - Letter

SN - 2365-709X

VL - 3

SP - 1

EP - 5

JO - Advanced Materials Technologies

JF - Advanced Materials Technologies

IS - 12

M1 - 1800205

ER -

A Fluorescence Intensity Ratiometric Fiber Optics–Based Chemical Sensor for Monitoring pH

Abstract

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