Nature of Cations Critically Affects Water at the Negatively Charged Silica Interface

Hunger, Johannes; Schaefer, John P.; Ober, Patrick; Seki, Takakazu; Wang, Yongkang; Prädel, Leon; Nagata, Yuki; Bonn, Mischa; Bonthuis, Douwe Jan; Backus, Ellen H. G.

doi:10.1021/jacs.2c02777

Cited by 35 publications

(43 citation statements)

References 68 publications

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“…By studying ion adsorption with and without background salts, we show that -OH region SFG signal is not always an ideal probe to infer ion adsorption, due to the ambiguity created by multiple effects, such as the hydration shell of the ions or interference effects. 30,[34][35] On the other hand, XFNTR cannot provide some details of ion distribution, because it is sensitive only to the total number of ions in both Stern and diffuse layers and insensitive to the reorganization of ions 4 between them. 28 Acknowledging the advantages and shortcomings of both methods allows elucidating the details of trivalent ion adsorption that cannot be determined by a single method.…”

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confidence: 99%

“…37 Studies with varying NaCl concentrations under AA monolayers have posited that the low signal in the water/AA system, which is comparable to a very high ionic strength system, is due to the destructive interference of SFG signal coming from the sample depth. 30,34 The persistence of OH signal at very high [NaCl] has been attributed to the finite size of the counterion (Na + ) which limits the charge screening when the Debye length is low. 37 With the addition of NdCl3 to the subphase, 3250 and 3550 cm -1 bands decrease gradually in contrast to the immediate decrease in the absence of the background salt (Figure 2b).…”

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confidence: 99%

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Elucidating Trivalent Ion Adsorption at Floating Carboxylic Acid Monolayers: Charge Reversal or Water Reorganization?

Nayak

Kumal

Lee

et al. 2023

Preprint

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We study trivalent neodymium adsorption on floating arachidic acid films at the air/water interface by two complementary surface specific probes, sum frequency generation (SFG) spectroscopy and X-ray fluorescence near total reflection (XFNTR). In the absence of background ions, neodymium ions compensate the surface charge of the arachidic acid film at 50 M bulk concentration without any charge reversal. Increasing the bulk concentration to 1 mM does not change the neodymium surface coverage but affects the interfacial water structure significantly. In the presence of a high concentration of background salt, NaCl, there is overcharging at 1mM of Nd3+ i.e., 30% more Nd3+ than needed to compensate the surface charge. The overcharging trend with and without salts is different than those observed at mineral/water interface, emphasizing the importance of surface properties. These results show that the total coverage of neodymium ions is not enough to describe the complete picture at the interface, and interfacial water and ion coverage needs to be considered together to understand more complex ion adsorption and transport processes.

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confidence: 99%

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confidence: 99%

Elucidating Trivalent Ion Adsorption at Floating Carboxylic Acid Monolayers: Charge Reversal or Water Reorganization?

Nayak

Kumal

Lee

et al. 2023

Preprint

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“…It is reasonable to assume that stronger hydrogen bonded water populations are farther into the bulk and weaker hydrogen bonded water populations are closer to the surface [33]. Indeed, we suggest that the 3400 cm -1 population is very close to the surface and possibly interacting with the GO, and 3600 cm -1 peak originates from the water molecules mostly trapped between the GO sheets.…”

Section: Identifying Water Populations With Different Hydrogen Bondin...mentioning

confidence: 72%

“…Previous SFG studies of the GO/aqueous interface only covered the latter of this concentration range that shows the decreasing SFG signal [35]. A recent study at the silica/water interface using lower concentrations demonstrated a similar increasing and decreasing trend [33]. However, the overall SFG intensity showed stronger cation specific effects due to significantly different chemistry of the silica surface compared to GO.…”

Section: Interfacial Water Structures Depend On the Salt Concentrationmentioning

confidence: 88%

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Monovalent Ion - Graphene Oxide Interactions are Controlled by Carboxylic Acid Groups: Sum Frequency Generation Spectroscopy Studies

Lee

Carr

Kumal

et al. 2023

Preprint

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Graphene oxide has been extensively researched for use in separating rare earth elements. The presence of monovalent ions during separation processes is inevitable and can impact the adsorption of target ions. To better understand how monovalent ions behave near graphene oxide surfaces, we conducted a systematic investigation using vibrational sum frequency generation spectroscopy to study the effects of alkali metal ions on water organization near graphene oxide thin films at the air/water interface. We used an arachidic acid Langmuir monolayer as a benchmark for a pure carboxylic acid surface. The sum frequency signal showed a nonmonotonic trend with increasing salt concentration, reaching a maximum at 100 µM and 1 mM salt concentrations for graphene oxide and arachidic acid, respectively. Theoretical modeling of the concentration-dependent sum frequency signal from graphene oxide and arachidic acid surfaces revealed that the adsorption of monovalent ions is mainly controlled by the carboxylic acid groups on graphene oxide. An in-depth analysis of sum frequency spectra revealed at least three distinct water populations with different hydrogen bonding strengths. Interestingly, interfacial water structure seemed mostly insensitive to the character of the alkali cation, in contrast to similar studies conducted at the silica/water interface. However, an ion-specific effect was observed with lithium, whose strong hydration prevented direct interactions with the graphene oxide film. Overall, our study provides molecular-scale insights into water structures near interfacial graphene oxide in the presence of monovalent ions, which can aid in the development of graphene oxide-based separations.

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Current understanding of ions and charged surfactants at aqueous solid interfaces

Bonthuis

2024

Encyclopedia of Solid-Liquid Interfaces

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Nature of Cations Critically Affects Water at the Negatively Charged Silica Interface

Cited by 35 publications

References 68 publications

Elucidating Trivalent Ion Adsorption at Floating Carboxylic Acid Monolayers: Charge Reversal or Water Reorganization?

Elucidating Trivalent Ion Adsorption at Floating Carboxylic Acid Monolayers: Charge Reversal or Water Reorganization?

Monovalent Ion - Graphene Oxide Interactions are Controlled by Carboxylic Acid Groups: Sum Frequency Generation Spectroscopy Studies

Current understanding of ions and charged surfactants at aqueous solid interfaces

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