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

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

doi:10.1002/admt.201800205

Cited by 34 publications

(28 citation statements)

References 54 publications

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“…In summary, we have shown that triangulenium-based dyes can be converted to redox probes by linking them to a redox sensitive motif. High photostability, long decay times and high yield synthesis are some of the arguments to further investigate triangulenium based indicators for sensor development [41,[50][51][52] as well as imaging purposes.…”

Section: Resultsmentioning

confidence: 99%

Evaluation of Ebselen-azadioxatriangulenium as redox-sensitive fluorescent intracellular probe and as indicator within a planar redox optode

et al. 2020

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Section: Resultsmentioning

confidence: 99%

Evaluation of Ebselen-azadioxatriangulenium as redox-sensitive fluorescent intracellular probe and as indicator within a planar redox optode

et al. 2020

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“…While only a few research studies have examined DCS [119,[121][122][123], chemical sensing materials are being studied for a wider variety of optical fiber applications, which could theoretically be used for the production of DCS to track corrosive external factors. For compatibility with OFS, there are a number of pH-sensing materials, including localized surface plasmon resonance (LSPR) Au or Ag nanoparticles (NP) integrated composites (Figure 13a) [124][125][126], organic dyes [127][128][129][130][131][132], fluorescent molecules [133][134][135][136][137], polymers [138][139][140][141], pH-sensitive hydrogel [142][143][144][145], etc. The pH value of the solution independent of the material embedded in the matrix is observed to be more integrated with the silica matrix coating [124,146].…”

Section: Distributed Ofs For Chemical Sensingmentioning

confidence: 99%

Review of Structural Health Monitoring Techniques in Pipeline and Wind Turbine Industries

Sharma

Singh

Gupta

et al. 2021

ASI

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There has been enormous growth in the energy sector in the new millennium, and it has enhanced energy demand, creating an exponential rise in the capital investment in the energy industry in the last few years. Regular monitoring of the health of industrial equipment is necessary, and thus, the concept of structural health monitoring (SHM) comes into play. In this paper, the purpose is to highlight the importance of SHM systems and various techniques primarily used in pipelining industries. There have been several advancements in SHM systems over the years such as Point OFS (optical fiber sensor) for Corrosion, Distributed OFS for physical and chemical sensing, etc. However, these advanced SHM technologies are at their nascent stages of development, and thus, there are several challenges that exist in the industries. The techniques based on acoustic, UAVs (Unmanned Aerial Vehicles), etc. bring in various challenges, as it becomes daunting to monitor the deformations from both sides by employing only one technique. In order to determine the damages well in advance, it is necessary that the sensor is positioned inside the pipes and gives the operators enough time to carry out the troubleshooting. However, the mentioned technologies have been unable to indicate the errors, and thus, there is the requirement for a newer technology to be developed. The purpose of this review manuscript is to enlighten the readers about the importance of structural health monitoring in pipeline and wind turbine industries.

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“…However, the decrease of the band at 660 nm is due to the overlap with the peak 595nm, as it has been confirmed DMQA has no fluorescence response to pH when it is in the gel phase. 41 The normalized and smoothed fluorescence spectra were shown in Figure S5, and the pH is evaluated by the ratiometric signal of the integrated peak areas (DAOTA/DMQA). By monitoring the sensors response to pH, we could see the responses are reversible and repeatable (Figure S6).…”

Section: Sensor Materials Synthesismentioning

confidence: 99%

“…21,40 We have described an organically modified silicon sol-gel that solves many of these issues, when it comes to creating a competitive optical pH sensor. 3,18,[41][42][43] The resulting sensor material has good chemical, photochemical and thermal stability as well as fast diffusion of H + , while excluding all other ions. The sensor material has the capacity to fully encapsulate the pH responsive dye, the ability to firmly stick to polymer and glass substrate, a long shelf-life and is fully biocompatible.…”

Section: Introductionmentioning

confidence: 99%

Incorporating Fluorescent Nanomaterials in Organically Modified Sol-Gel Materials – Creating Single Composite Optical pH Sensors

Bartos¹,

Rewers²,

Wang³

et al. 2021

Preprint

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<br><br>Optical sensors hold the promise of providing the coupling between the tangible and the digital world that we are currently experiencing with physical sensors. The core of optical sensor development lies in materials development, where specific requirements of opposing physicochemical properties create a significant obstacle. The sensor material must provide dye retention, while ensuring porosity for analyte transport. The sensor material must provide hydrophobic pockets for dyes to ensure high signal intensity, while remaining fully hydrophobic to measure in water. We have previously reported optical sensors, where we compromised on sensor manufacturing by using a double-layer composite. Here, we report a composite organically modified sol-gel (ORMOSIL) polymer, where polystyrene (PS) nanoparticles (NPs) have been incorporated. This allows all the opposing requirements on optical sensor materials to be fulfilled, and by introducing a hydrophobic reference dye in the fully hydrophobic compartments of the sensor material we show that we can incorporate any hydrophobic fluorophore in this material, even those which are suffering from quenching in water. In this work, PS NPs with 1,13-dimethoxyquinacridinium (DMQA) were immobilized in a composite sol-gel material with pH responsive diazaoxatriangulenium (DAOTA) dyes prior to curing. The multicomponent sensor composite was cured on a polycarbonate hemiwicking substrate, and the resulting fluorescence intensity ratiometric optical pH sensor was shown to have excellent performance. We expect that this type of composite sensor materials will allow the creation of next generation industrial chemosensors.<br><br>

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

Cited by 34 publications

References 54 publications

Evaluation of Ebselen-azadioxatriangulenium as redox-sensitive fluorescent intracellular probe and as indicator within a planar redox optode

Evaluation of Ebselen-azadioxatriangulenium as redox-sensitive fluorescent intracellular probe and as indicator within a planar redox optode

Review of Structural Health Monitoring Techniques in Pipeline and Wind Turbine Industries

Incorporating Fluorescent Nanomaterials in Organically Modified Sol-Gel Materials – Creating Single Composite Optical pH Sensors

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