Potentiostatic infrared titration of 11-mercaptoundecanoic acid monolayers

Luque, A.; Cuesta, Ángel; Calvente, Juan José; Andreu, Rafael

doi:10.1016/j.elecom.2014.05.011

Cited by 16 publications

(24 citation statements)

References 32 publications

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“…the uncoordinated carboxylic group seems also to be lowered in comparison to the second pKa for the corresponding dissolved species in an extent that decreases as the size of the molecule increases from (hydrogen)oxalate to (hydrogen)succinate [71]. In other cases, such as bisulfate [72] and mercaptoundecanoic acid [73] dissolved carbon dioxide (this latter species being hardly detected in the ATR-SEIRA spectra). In the case of platinum electrodes, it was clear from previous infrared external reflection data for SQA oxidation that carbon dioxide is produced [24,28].…”

Section: Accepted Manuscriptmentioning

confidence: 94%

Squaric acid adsorption and oxidation at gold and platinum electrodes

Cheuquepán

Martínez-Olivares

Rodes

et al. 2018

Journal of Electroanalytical Chemistry

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The adsorption and oxidation of squaric acid (3,4-dihydroxycyclobut-3-ene-1,2-dione, H 2 C 4 O 4 , SQA) at platinum and gold electrodes were studied spectroelectrochemically in perchloric acid solutions. Voltammetric experiments demonstrate that reversible adsorption takes place at gold electrodes in the double-layer region. As a difference with platinum electrodes, no dissociative adsorption processes leading to the blocking of the electrode surface are detected. ATR-SEIRAS experiments show potential-dependent adsorbate bands at potentials below 1.20 V RHE that, according to DFT calculations, can be assigned to adsorbed squarate. For platinum electrodes, the potential-dependent adsorption of squarate anions is coupled with the oxidative stripping of adsorbed carbon monoxide, which is formed upon dissociative SQA adsorption. Bonding of squarate species to the platinum and gold surfaces involves two oxygen atoms in a bidentate configuration, with the molecular plane perpendicular to the metal surface. The ATR-SEIRA spectra obtained for gold electrodes in the SQA oxidation region show bands for adsorbed bicarbonate anions formed from dissolved carbon dioxide molecules. In the case of platinum, distinct bands are observed for adsorbed oxidation products which probably are formed upon opening of the SQA ring.

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Section: Accepted Manuscriptmentioning

confidence: 94%

Squaric acid adsorption and oxidation at gold and platinum electrodes

Cheuquepán

Martínez-Olivares

Rodes

et al. 2018

Journal of Electroanalytical Chemistry

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“…This is similar to a recent work in which the pH-and potential-dependent ratio between the integrated intensities of the carbonyl and carboxylate bands in ATR-SEIRA spectra of self-assembled monolayers (SAMs) of 11-mercaptoundecanoic acid (MUA) was used to determine the pK a of MUA in the SAM. 22 The proximity between ߥ COO, asym and the H-O-H bending mode of water (ߜ HOH ) also needs to be taken into account. As shown recently by Yamakata et al using CO-covered Pt electrodes, [23][24][25] ATR-SEIRAS can be used to obtain the vibrational spectrum of the hydration layer of the cations of the supporting electrolyte at the electrode-electrolyte interface.…”

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confidence: 99%

Spectroscopic Evidence of Size-Dependent Buffering of Interfacial pH by Cation Hydrolysis during CO₂ Electroreduction

Ayemoba

Cuesta

2017

ACS Appl. Mater. Interfaces

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The nature of the electrolyte cation is known to affect the Faradaic efficiency and selectivity of CO electroreduction. Singh et al. (J. Am. Chem. Soc. 2016, 138, 13006-13012) recently attributed this effect to the buffering ability of cation hydrolysis at the electrical double layer. According to them, the pK of hydrolysis decreases close to the cathode due to the polarization of the solvation water molecules sandwiched between the cation's positive charge and the negative charge on the electrode surface. We have tested this hypothesis experimentally, by probing the pH at the gold-electrolyte interface in situ using ATR-SEIRAS. The ratio between the integrated intensity of the CO and HCO bands, which has to be inversely proportional to the concentration of H, provided a means to determining the pH change at the electrode-electrolyte interface in situ during the electroreduction of CO. Our results confirm that the magnitude of the pH increase at the interface follows the trend Li > Na > K > Cs, adding strong experimental support to Singh's et al.'s hypothesis. We show, however, that the pH buffering effect was overestimated by Singh et al., their overestimation being larger the larger the cation. Moreover, our results show that the activity trend of the alkali-metal cations can be inverted in the presence of impurities that alter the buffering effect of the electrolyte, although the electrolyte with maximum activity is always that for which the increase in the interfacial pH is smaller.

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“…Degree of acid dissociation (pK a ) is a function of solution composition [1][2][3] and identity of neighbouring charged species. 4,5 For example, it is common for acid groups within enzymes to have pK a values that vary as a function of local charge in the active site.…”

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“…1 Protonation states of electrode-immobilized acids are also found to vary with applied potential. 2,3,6,7 Some studies find that acid association takes place on application of a negative potential and have proposed that protonation is driven by the applied electric field. 6,7 This electrochemically driven reversible acid protonation reaction has been exploited to fabricate a fast charge-discharge supercapacitor from 3,4,9,10-perylene tetracarboxylic acid adsorbed on graphene layers.…”

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confidence: 99%

“…8 Conversely, other studies have found that deprotonation takes place when a negative potential is applied and is driven by a local increase in cation activity at the electrode interface that lowers the effective pK a of the acid groups. 2,3 pK a is defined in terms of acid dissociation but neglects the effect of concomitant interaction of the conjugate base with solution cations. The resulting apparent pK a (pK a (app)) can be shown 2 (S1, ESI †) to depend on monovalent cation activity a M + and K as , the equilibrium constant for the association between conjugate base and solution cations, as shown in eqn (1): pK a (app) = pK a + pK as À log(a M +)…”

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confidence: 99%

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