A versatile optode system for oxygen, carbon dioxide, and pH measurements in seawater with integrated battery and logger

Staudinger, Christoph; Štrobl, Martin; Fischer, Jan; Thar, Roland; Mayr, Torsten; Aigner, Daniel; Müller, Bernhard; Lehner, Philipp; Mistlberger, Günter; Fritzsche, Eva; Ehgartner, Josef; Zach, Peter; Clarke, Jennifer S.; Geißler, Felix; Mutzberg, André; Müller, Jens Daniel; Achterberg, Eric P.; Borisov, Sergey M.; Klimant, Ingo

doi:10.1002/lom3.10260

Cited by 37 publications

(32 citation statements)

References 67 publications

(90 reference statements)

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“…Whereas stability of the chromophore can be adequate for relatively short-term usage (e.g., in disposable sensors), it may not be the case if the sensor has to maintain high accuracy during many months without possibility of recalibration (like on Argo floats in oceanography). For instance, BF 2 chelated chromophores (BODIPYs and aza-BODIPYs) may exhibit slow decomposition in aqueous media, the drift being temperature-dependent 537 and probably pH dependent. Photostability is a critical parameter if high light intensities are involved (e.g., in microscopy or in fiber-optic microsensors).…”

Section: Overview Of Commonly Used Luminescent Ph Probesmentioning

confidence: 99%

Optical Sensing and Imaging of pH Values: Spectroscopies, Materials, and Applications

2020

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This is the first comprehensive review on methods and materials for use in optical sensing of pH values and on applications of such sensors. The Review starts with an introduction that contains subsections on the definition of the pH value, a brief look back on optical methods for sensing of pH, on the effects of ionic strength on pH values and p K a values, on the selectivity, sensitivity, precision, dynamic ranges, and temperature dependence of such sensors. Commonly used optical sensing schemes are covered in a next main chapter, with subsections on methods based on absorptiometry, reflectometry, luminescence, refractive index, surface plasmon resonance, photonic crystals, turbidity, mechanical displacement, interferometry, and solvatochromism. This is followed by sections on absorptiometric and luminescent molecular probes for use pH in sensors. Further large sections cover polymeric hosts and supports, and methods for immobilization of indicator dyes. Further and more specific sections summarize the state of the art in materials with dual functionality (indicator and host), nanomaterials, sensors based on upconversion and 2-photon absorption, multiparameter sensors, imaging, and sensors for extreme pH values. A chapter on the many sensing formats has subsections on planar, fiber optic, evanescent wave, refractive index, surface plasmon resonance and holography based sensor designs, and on distributed sensing. Another section summarizes selected applications in areas, such as medicine, biology, oceanography, bioprocess monitoring, corrosion studies, on the use of pH sensors as transducers in biosensors and chemical sensors, and their integration into flow-injection analyzers, microfluidic devices, and lab-on-a-chip systems. An extra section is devoted to current challenges, with subsections on challenges of general nature and those of specific nature. A concluding section gives an outlook on potential future trends and perspectives.

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Section: Overview Of Commonly Used Luminescent Ph Probesmentioning

confidence: 99%

Optical Sensing and Imaging of pH Values: Spectroscopies, Materials, and Applications

2020

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“…An intelligent dissolved oxygen sensor can perform analog and digital signal processing on the collected dissolved oxygen signals, realize intelligent transmission, and achieve a “plug and play” effect. At the same time, through the combination of software and hardware, the intelligent dissolved oxygen sensor can compensate for and correct the detection results in real time [21]. In short, the intelligent dissolved oxygen sensor has the ability of real-time signal acquisition and intelligent data processing, which can meet the requirements of the long-term in situ measurement of the dissolved oxygen content, and effectively overcome the problems of the traditional detection technology [22].…”

Section: Introductionmentioning

confidence: 99%

Review of Dissolved Oxygen Detection Technology: From Laboratory Analysis to Online Intelligent Detection

Wei

Jiao

et al. 2019

Sensors

110

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Dissolved oxygen is an important index to evaluate water quality, and its concentration is of great significance in industrial production, environmental monitoring, aquaculture, food production, and other fields. As its change is a continuous dynamic process, the dissolved oxygen concentration needs to be accurately measured in real time. In this paper, the principles, main applications, advantages, and disadvantages of iodometric titration, electrochemical detection, and optical detection, which are commonly used dissolved oxygen detection methods, are systematically analyzed and summarized. The detection mechanisms and materials of electrochemical and optical detection methods are examined and reviewed. Because external environmental factors readily cause interferences in dissolved oxygen detection, the traditional detection methods cannot adequately meet the accuracy, real-time, stability, and other measurement requirements; thus, it is urgent to use intelligent methods to make up for these deficiencies. This paper studies the application of intelligent technology in intelligent signal transfer processing, digital signal processing, and the real-time dynamic adaptive compensation and correction of dissolved oxygen sensors. The combined application of optical detection technology, new fluorescence-sensitive materials, and intelligent technology is the focus of future research on dissolved oxygen sensors.

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“…where J air-water is the exchange rate, or vertical flux, of the gas (positive upward), C water is the gas bulk concentration below the film on the water-side, C air is the concentration above the film on the air-side, and k is the gas exchange coefficient, often also referred to as the "gas transfer velocity" or "piston velocity." For most gases, C water and C air are straightforward to measure continuously in situ with modern autonomous sensors (Koopmans and Berg 2015;Fritzsche et al 2017;Staudinger et al 2018) or calculate from known relationships, whereas the complexity of gas exchange and its many controlling variables are contained entirely in k (Macintyre et al 1995;McKenna and McGillis 2004;Cole et al 2010). Estimating k from Eq.…”

Section: Calculations Of Gas Exchange Coefficientsmentioning

confidence: 99%

“…Despite the complexity of processes that control air–water gas exchange, the widely used expression for its magnitude is simple and assumes conceptually that gas is transported by molecular diffusion across intact boundary layers, or thin films, on each side of the interface (Whitman 1923; Liss and Slater 1974):

J_{air - water} = k ((), C_{water} - C_{air})

where J air–water is the exchange rate, or vertical flux, of the gas (positive upward), C water is the gas bulk concentration below the film on the water‐side, C air is the concentration above the film on the air‐side, and k is the gas exchange coefficient, often also referred to as the “gas transfer velocity” or “piston velocity.” For most gases, C water and C air are straightforward to measure continuously in situ with modern autonomous sensors (Koopmans and Berg 2015; Fritzsche et al 2017; Staudinger et al 2018) or calculate from known relationships, whereas the complexity of gas exchange and its many controlling variables are contained entirely in k (Macintyre et al 1995; McKenna and McGillis 2004; Cole et al 2010).…”

Section: Use Materials and Proceduresmentioning

confidence: 99%

Air–water gas exchange in lakes and reservoirs measured from a moving platform by underwater eddy covariance

Berg

Pace

Buelo

2020

Limnology & Ocean Methods

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Air-water exchange rates of gasses, such as O 2 , CO 2 , and CH 4 , are widely used in ecosystem studies of lakes and reservoirs, but their magnitudes are often difficult to assess. In this proof-of-concept study, we measured gas exchange by underwater eddy covariance in such lentic systems from a moving platform. We used an Acoustic Doppler Velocimeter and a fast-responding O 2-temperature sensor mounted in the bow of a boat to measure water velocity, O 2 concentration, and temperature below the air-water interface (10 cm) while the boat was propelled at constant speed (25 cm s −1) by an electric trolling motor. Fluxes of O 2 and heat across the airwater interface and standard gas exchange coefficients, k 600 , were calculated for every 3 min of traveled distance (45 m). All deployments were done under calm low-wind conditions where empirical relationships for k 600 are most uncertain. Deployment averages of k 600 ranged from 0.070 to 0.39 m d −1 and were strongly correlated with both the heat flux and the water temperature. In one deployment, a > 20% variation in mean water column O 2 concentration was measured along a 1 km long transect of a reservoir. Given the typical size of O 2 concentration differences over the air-water interface that drive gas exchange, such lateral variations can, even at a near-constant exchange coefficient, result in highly biased whole-ecosystem fluxes if based on stationary singlepoint O 2 measurements. "Mobile" aquatic eddy covariance measurements enable quantification of gas exchange in lakes and reservoirs under true in situ conditions and with high temporal and spatial resolution.

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A versatile optode system for oxygen, carbon dioxide, and pH measurements in seawater with integrated battery and logger

Cited by 37 publications

References 67 publications

Optical Sensing and Imaging of pH Values: Spectroscopies, Materials, and Applications

Optical Sensing and Imaging of pH Values: Spectroscopies, Materials, and Applications

Review of Dissolved Oxygen Detection Technology: From Laboratory Analysis to Online Intelligent Detection

Air–water gas exchange in lakes and reservoirs measured from a moving platform by underwater eddy covariance

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