Thin‐Layer Chemical Modulations by a Combined Selective Proton Pump and pH Probe for Direct Alkalinity Detection

Afshar, Majid Ghahraman; Crespo, Gastón A.; Bakker, Eric

doi:10.1002/anie.201500797

Cited by 32 publications

(50 citation statements)

References 27 publications

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“…Successful deployments of lab-on-chip devices on underwater gliders have been demonstrated for nitrate [153]. Innovative TA sensors that generate hydrogen ions in situ through coulometry [122] or ionselective membranes [123] to conduct chronopotentiometric titrations have also been demonstrated in the laboratory. These sensors are small, solid state, and low power, making them promising candidates for in situ sensing applications.…”

Section: Emerging Technologiesmentioning

confidence: 99%

Observing Changes in Ocean Carbonate Chemistry: Our Autonomous Future

Bushinsky

Takeshita

Williams

2019

Curr Clim Change Rep

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Purpose of Review We summarize recent progress on autonomous observations of ocean carbonate chemistry and the development of a network of sensors capable of observing carbonate processes at multiple temporal and spatial scales. Recent Findings The development of versatile pH sensors suitable for both deployment on autonomous vehicles and in compact, fixed ecosystem observatories has been a major development in the field. The initial large-scale deployment of profiling floats equipped with these new pH sensors in the Southern Ocean has demonstrated the feasibility of a global autonomous open-ocean carbonate observing system. Summary Our developing network of autonomous carbonate observations is currently targeted at surface ocean CO 2 fluxes and compact ecosystem observatories. New integration of developed sensors on gliders and surface vehicles will increase our coastal and regional observational capability. Most autonomous platforms observe a single carbonate parameter, which leaves us reliant on the use of empirical relationships to constrain the rest of the carbonate system. Sensors now in development promise the ability to observe multiple carbonate system parameters from a range of vehicles in the near future.

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Section: Emerging Technologiesmentioning

confidence: 99%

Observing Changes in Ocean Carbonate Chemistry: Our Autonomous Future

Bushinsky

Takeshita

Williams

2019

Curr Clim Change Rep

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“…We have also explored thin layer gap electrodes where two membrane electrodes face each other, separated just by a thin space that allows for rapid equilibration. [54] One membrane perturbs the solution by an instrumentally imposed ion flux while the opposite membrane serves as detection electrode. This principle has been used to detect total alkalinity in environmental samples without the need for volumetric titration.…”

Section: Dynamic Potentiometry: Polyion Sensorsmentioning

confidence: 99%

A Scientific Journey with Ionophore-based Sensors

Bakker

2020

Chimia

Self Cite

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This article describes selected historical milestones in the field of neutral ionophore-based sensors, starting with the first discovery by Wilhelm Simon and their impact to analytical sciences despite the initial difficulty to understand their function. The reader is then guided through topics in which the author has been involved over the years, from understanding thermodynamic aspects to the field of non-equilibrium potentiometry, polyion sensors, trace level potentiometry, instrumentally controlled ion sensors and finally potentiometry involving local perturbations and transient currents that allow for new readout possibilities. Discussed applications include clinical diagnostics, environmental in situ sensing/profiling and speciation analysis. The article loosely follows the content of the Simon-Widmer Award lecture of the same title presented by the author at the CH Analysis 2019 conference in Beatenberg, Switzerland.

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“…[19] Nanochannels with rectifying characteristics can be roughly divided into two types:h omogeneous structures [20] and heterostructures. [21,22] In general, stimulusresponsive gating, such as pH gating [23][24][25] and light-responsive gating, [26][27][28] can be achieved by the functional modification of the inner surface of the nanochannel. However,t he ion selectivity of these two types of structures acts at the microscale level, and the origin of ion selectivity at the nanoscale warrants further investigation.…”

Section: Introductionmentioning

confidence: 99%

Self‐Assembled Gold Arrays That Allow Rectification by Nanoscale Selectivity

Cai

et al. 2019

Angew Chem Int Ed

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The deposition of a monolayer nanoarray on the surface of a micrometer‐thick substrate is demonstrated, producing rectification characteristics at the nanoscale. The experimental results show that the heterogeneity of the structure and the charge density are the two key factors affecting rectification, which was confirmed with molecular dynamic (MD) and finite element simulations. Moreover, by altering the asymmetric electrolyte environment, the fabricated heterogeneous membrane can be used in energy conversion. This study provides insights into the mechanism underlying the generation of rectification and related factors, providing a theoretical basis for the characteristics of rectification.

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Thin‐Layer Chemical Modulations by a Combined Selective Proton Pump and pH Probe for Direct Alkalinity Detection

Cited by 32 publications

References 27 publications

Observing Changes in Ocean Carbonate Chemistry: Our Autonomous Future

Observing Changes in Ocean Carbonate Chemistry: Our Autonomous Future

A Scientific Journey with Ionophore-based Sensors

Self‐Assembled Gold Arrays That Allow Rectification by Nanoscale Selectivity

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