Laura C. Dzugan scite author profile

The Grotthuss mechanism explains the anomalously high proton mobility in water as a sequence of proton transfers along a hydrogen-bonded (H-bonded) network. However, the vibrational spectroscopic signatures of this process are masked by the diffuse nature of the key bands in bulk water. Here we report how the much simpler vibrational spectra of cold, composition-selected heavy water clusters, D(DO), can be exploited to capture clear markers that encode the collective reaction coordinate along the proton-transfer event. By complexing the solvated hydronium "Eigen" cluster [DO(DO)] with increasingly strong H-bond acceptor molecules (D, N, CO, and DO), we are able to track the frequency of every O-D stretch vibration in the complex as the transferring hydron is incrementally pulled from the central hydronium to a neighboring water molecule.

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Microhydration of Contact Ion Pairs in M²⁺OH^–(H₂O)_n=1–5 (M = Mg, Ca) Clusters: Spectral Manifestations of a Mobile Proton Defect in the First Hydration Shell

Johnson

Dzugan

Wolk

et al. 2014

J. Phys. Chem. A

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Vibrational predissociation spectra of D2-"tagged" Mg(2+)OH(-)(H2O)n=1-6 and Ca(2+)OH(-)(H2O)n=1-5 clusters are reported to explore how the M(2+)OH(-) contact ion pairs respond to stepwise formation of the first hydration shell. In both cases, the hydroxide stretching frequency is found to red-shift strongly starting with addition of the third water molecule, quickly becoming indistinguishable from nonbonded OH groups associated with solvent water molecules by n = 5. A remarkably broad feature centered around 3200 cm(-1) and spanning up to ∼1000 cm(-1) appears for the n ≥ 4 clusters that we assign to a single-donor ionic hydrogen bond between a proximal first solvent shell water molecule and the embedded hydroxide ion. The extreme broadening is rationalized with a theoretical model that evaluates the range of local OH stretching frequencies predicted for the heavy particle configurations available in the zero-point vibrational wave function describing the low-frequency modes. The implication of this treatment is that extreme broadening in the vibrational spectrum need not arise from thermal fluctuations in the ion ensemble, but can rather reflect combination bands based on the OH stretching fundamental that involve many quanta of low-frequency modes whose displacements strongly modulate the OH stretching frequency.

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Comparison of the Effects of Biofouling on Voltammetric and Potentiometric Measurements

2012

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Biofouling of sensors is a common problem when measuring biological samples. The adherence of proteins and biomolecules, called hemostasis, is the first of four steps that lead to biofouling and eventually a foreign body response. This typically occurs within the first hours after the exposure of the biosensor to a biological sample. The purpose of this study was to assess the effect of this initial step of biofouling on cyclic voltammetry and potentiometric measurements. The results show that biofouling occurred rapidly within minutes and strongly affected cyclic voltammetry measurements, while potentiometric measurements were minimally affected even after 24 hours.

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Spectral signatures of proton delocalization in H⁺(H₂O)_n=1−4 ions

et al. 2018

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Laura C. Dzugan

Spectroscopic snapshots of the proton-transfer mechanism in water

Microhydration of Contact Ion Pairs in M²⁺OH^–(H₂O)_n=1–5 (M = Mg, Ca) Clusters: Spectral Manifestations of a Mobile Proton Defect in the First Hydration Shell

Comparison of the Effects of Biofouling on Voltammetric and Potentiometric Measurements

Spectral signatures of proton delocalization in H⁺(H₂O)_n=1−4 ions

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About

Laura C. Dzugan

Spectroscopic snapshots of the proton-transfer mechanism in water

Microhydration of Contact Ion Pairs in M2+OH–(H2O)n=1–5 (M = Mg, Ca) Clusters: Spectral Manifestations of a Mobile Proton Defect in the First Hydration Shell

Comparison of the Effects of Biofouling on Voltammetric and Potentiometric Measurements

Spectral signatures of proton delocalization in H+(H2O)n=1−4 ions

Contact Info

Product

Resources

About

Microhydration of Contact Ion Pairs in M²⁺OH^–(H₂O)_n=1–5 (M = Mg, Ca) Clusters: Spectral Manifestations of a Mobile Proton Defect in the First Hydration Shell

Spectral signatures of proton delocalization in H⁺(H₂O)_n=1−4 ions