Imaging of CO<sub>2</sub> and Dissolved Inorganic Carbon via Electrochemical Acidification–Optode Tandem

Wiorek, Alexander; Steininger, Fabian; Crespo, Gastón A.; Cuartero, María; Koren, Klaus

doi:10.1021/acssensors.3c00790

Cited by 5 publications

(2 citation statements)

References 36 publications

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“…This result agrees with the uptake measured by potentiometry (Figure d) and confirms the capability of the CNT-ISM actuator to alkalinize the sample without the need of adding an external reagent. Notably, reagentless approaches based on solid-state materials able to modulate the sample pH are on the rise today. − This, in combination with either optical or electrochemical sensors, has already allowed for the development of disruptive analytical concepts. Some examples where alkalinization with the CNT-ISM actuator may be of interest include precipitation of cocaine for its electrochemical detection in complex powders (dissolved in water) and speciation of nitrogen (NH 3 /NH 4 + ) in environmental systems (e.g., waters and soils) …”

Section: Resultsmentioning

confidence: 99%

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Wiorek,

Cuartero,

Crespo

2023

Anal. Chem.

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Herein, we investigate the selective deionization (i.e., the removal of ions) in thin-layer samples (<100 μm in thickness) using carbon nanotubes (CNTs) covered with an ionophore-based ion-selective membrane (ISM), resulting in a CNT-ISM tandem actuator. The concept of selective deionization is based on a recent discovery by our group (Anal. Chem.20229474557459), where the activation of the CNT-ISM architecture is conceived on a mild potential step that charges the CNTs to ultimately generate the depletion of ions in a thin-layer sample. The role of the ISM is to selectively facilitate the transport of only one ion species to the CNT lattice. To estimate the deionization efficiency of such a process, a potentiometric sensor is placed less than 100 μm away from the CNT-ISM tandem, inside a microfluidic cell. This configuration helped to reveal that the selective uptake of ions increases with the capacitance of the CNTs and that the ISM requires a certain ion-exchanger capacity, but this does not further affect its efficiency. The versatility of the concept is demonstrated by comparing the selective uptake of five different ions (H+, Li+, Na+, K+, and Ca2+), suggesting the possibility to remove any cation from a sample by simply changing the ionophore in the ISM. Furthermore, ISMs based on two ionophores proved to achieve the simultaneous and selective deionization of two ion species using the same actuator. Importantly, the relative uptake between the two ions was found to be governed by the ion–ionophore binding constants, with the most strongly bound ion being favored over other ions. The CNT-ISM actuator concept is expected to contribute to the analytical sensing field in the sense that ionic interferents influencing the analytical signal can selectively be removed from samples to lower traditional limits of detection.

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Section: Resultsmentioning

confidence: 99%

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Wiorek,

Cuartero,

Crespo

2023

Anal. Chem.

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“…In a follow-up study, Wiorek et al combined the same 2D proton pump with a CO 2 optode, enabling the imaging of dissolved CO 2 and subsequently total dissolved inorganic carbon (DIC). 69 Based on those two images, total alkalinity, and pH images can also be calculated based on certain assumptions. Thus, this setup represents a four-parameter imaging approach (Fig.…”

Section: The Road To Multiparameter Sensorsmentioning

confidence: 99%

Optical sensors (optodes) for multiparameter chemical imaging: classification, challenges, and prospects

Kalinichev,

Zieger,

Koren

2024

Analyst

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In Situ pH Modulation for Enhanced Chemical Sensing: Strategies and Applications

Steininger,

Koren

2024

Analysis & Sensing

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AbstractpH is one of the key parameters in chemistry and impacts almost all chemical and biological processes. Also, within analytical chemistry and sensing, pH plays a critical role. This review underscores the critical role of pH manipulation in overcoming analytical challenges posed by complex sample matrices and dynamic environmental conditions. It explores the available tools to control pH at a local scale and how those are or can be applied to improve sensor performance. We focus on four key areas where pH modulation has been or could be leveraged to advance chemical sensing capabilities: i) sensing alkalinity and buffer capacity, ii) sample pretreatment, iii) sensing pH dependent analytes and iv) reducing biofouling. We analyze existing strategies, but also try to identify unexplored possibilities which may have potential and can be exploited for sensing.

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Imaging of CO₂ and Dissolved Inorganic Carbon via Electrochemical Acidification–Optode Tandem

Cited by 5 publications

References 36 publications

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Optical sensors (optodes) for multiparameter chemical imaging: classification, challenges, and prospects

In Situ pH Modulation for Enhanced Chemical Sensing: Strategies and Applications

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Imaging of CO2 and Dissolved Inorganic Carbon via Electrochemical Acidification–Optode Tandem

Cited by 5 publications

References 36 publications

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes–Polymeric Membranes

Optical sensors (optodes) for multiparameter chemical imaging: classification, challenges, and prospects

In Situ pH Modulation for Enhanced Chemical Sensing: Strategies and Applications

Contact Info

Product

Resources

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Imaging of CO₂ and Dissolved Inorganic Carbon via Electrochemical Acidification–Optode Tandem