Mechanism of ion adsorption to aqueous interfaces: Graphene/water vs. air/water

McCaffrey, Debra L.; Nguyen, Son C.; Cox, Stephen J.; Weller, Horst; Alivisatos, A. Paul; Geissler, Phillip L.; Saykally, Richard J.

doi:10.1073/pnas.1702760114

Cited by 91 publications

(116 citation statements)

References 44 publications

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“…12 It is known that deviations from ideal solvent behavior are related to specific ion effects. [13][14] Although recent experimental, 11,[15][16][17] computational, 18 and theoretical [19][20] advances have improved our understanding considerably, the emerging view is that specific ion effects may not have a single unified explanation, especially when ion-ion interactions and interfacial ion-binding sites are operative. 17 The interfacial interactions of biologically relevant, and usually lighter, ions in aqueous environments have been extensively studied.…”

Section: Introductionmentioning

confidence: 99%

Heavy Anionic Complex Creates a Unique Water Structure at a Soft Charged Interface

et al. 2018

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Ion hydration and interfacial water play crucial roles in numerous phenomena ranging from biological to industrial systems. Although biologically relevant (and mostly smaller) ions have been studied extensively in this context, very little experimental data exist about molecular scale behavior of heavy ions and their complexes at interfaces, especially under technologically significant conditions. It has recently been shown that PtCl6 2complexes adsorb at positively charged interfaces in a two-step process that cannot fit into well-known empirical trends, such as Hofmeister series. Here, a combined vibrational sum frequency generation and molecular dynamics study reveals that a unique interfacial water structure is connected to this peculiar adsorption behavior. A novel sub-ensemble analysis of MD simulation results show that after adsorption, PtCl6 2complexes partially retain their first and second hydration spheres, and it is possible to identify three different types of water molecules around them based on their orientational structures and hydrogen bonding strengths. These results have important implications for relating interfacial water structure and hydration enthalpy to the general understanding of specific ion effects. This in turn influences interpretation of heavy metal ion distribution across and reactivity within, liquid interfaces.

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Section: Introductionmentioning

confidence: 99%

Heavy Anionic Complex Creates a Unique Water Structure at a Soft Charged Interface

et al. 2018

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“…4 Of particular interest is the behavior of ions at interfaces ranging from air/water and polymer/water to metal/water. Recent advances in experiment and theory have revealed mechanistic details of the adsorption of the prototypical thiocyanate ion to air/water, 5,6 dodecanol/water, 7 and graphene/water 8 interfaces, focusing on thermodynamic properties (viz. adsorption free energy, enthalpy, and entropy).…”

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confidence: 99%

Charge-Transfer-to-Solvent Spectrum of Thiocyanate at the Air/Water Interface Measured by Broadband Deep Ultraviolet Electronic Sum Frequency Generation Spectroscopy

Mizuno

Rizzuto

Saykally

2018

J. Phys. Chem. Lett.

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Measurement of interfacial electronic spectra is a powerful tool for characterizing the properties of ions in physical, biological, environmental, and industrial systems. Here, we describe measurement of the complete charge-transfer-to-solvent (CTTS) spectrum of thiocyanate at the air/water interface using our recently developed femtosecond broadband deep ultraviolet electronic sum frequency generation technique. We find that the lower energy CTTS band characterized in bulk thiocyanate spectra is not observed in the | χ|-power spectrum of the air/water interface, likely reflecting the different solvation environments, altering of the charge distribution of the ion, and possible ion-ion effects, and that sodium and potassium salts yield identical spectra. Additional experiments and comparison with theoretical calculations are necessary to extract the interesting chemical details responsible for these salient spectral differences.

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“…This again is consistent with the assumption of ion adsorption on graphene. It has been shown by molecular dynamics simulations that graphene could attract, due to π-conjunction and polarizability, both cations [59][60][61] and anions [62,63], such as Na + (ρ = 86.75×10 -6 Å -2 ) and K + (ρ = 55.06×10 -6 Å -2 ) in PBS to the graphene-water interface. Furthermore, the fitted SLD profiles to the XRR curves of the soaked graphene in PBS at 25 °C ( Figure 5c) and 60 °C ( Figure 5d) also show that ion adsorption was promoted upon heating.…”

Section: A N U S C R I P Tmentioning

confidence: 99%

Graphene surface structure in aqueous media: Evidence for an air-bubble layer and ion adsorption

Zhou

Islas

Taylor

et al. 2019

Carbon

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Mechanism of ion adsorption to aqueous interfaces: Graphene/water vs. air/water

Cited by 91 publications

References 44 publications

Heavy Anionic Complex Creates a Unique Water Structure at a Soft Charged Interface

Heavy Anionic Complex Creates a Unique Water Structure at a Soft Charged Interface

Charge-Transfer-to-Solvent Spectrum of Thiocyanate at the Air/Water Interface Measured by Broadband Deep Ultraviolet Electronic Sum Frequency Generation Spectroscopy

Graphene surface structure in aqueous media: Evidence for an air-bubble layer and ion adsorption

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