Substrate-Mediated Interaction on Ag(111) Surfaces from First Principles

Fichthorn, Kristen A.; Scheffler, Matthias

doi:10.1007/978-94-010-0816-7_20

Cited by 3 publications

(2 citation statements)

References 28 publications

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“…Moreover, the long-range interaction between adatoms on metallic surfaces has been found to be oscillatory, with a period of half the Fermi wavelength, with identification of several minima and maxima up to distances as large as 70 Å . In the field of density functional calculations, nonmonotonic behavior of the pair interaction between adatoms has been observed by Fichthorn for adsorption of Ag on Ag(111) strained and unstrained surfaces. , …”

Section: Resultsmentioning

confidence: 94%

On the Stability of Ag/Au(111) Expanded Structures

2002

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In this work, we present a series of first-principles calculations on the stability of expanded silver monolayers adsorbed on a gold (111) substrate. The main result obtained is that none of the structures that are more expanded than the (1 × 1) compact monolayer is more stable than the bulk silver phase and hence should not be underpotentially deposited. A possible explanation for the discrepancy between experimental and theoretical results may lie in the strong work function shift generated by the adsorbate. This may produce large electric fields at the interface, modifying the binding energy and promoting anion adsorption through a negative shift in the potential of zero charge.

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Section: Resultsmentioning

confidence: 94%

On the Stability of Ag/Au(111) Expanded Structures

2002

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“…The first-principles DFT calculations were conducted by the Vienna Ab initio Simulation Package via the projector augmented wave method. , The exchange functional was treated by using the generalized gradient approximation of the Perdew–Burke–Ernzerhof functional . Here, the energy cutoff was set as 450 eV for the plane wave basis expansion, and the force on atoms was less than 0.03 eV/Å for the convergence criterion of geometry relaxation.…”

Section: Methodsmentioning

confidence: 99%

Metallic Mo₂C Quantum Dots Confined in Functional Carbon Nanofiber Films toward Efficient Sodium Storage: Heterogeneous Interface Engineering and Charge-Storage Mechanism

Wang

Sun

et al. 2021

ACS Appl. Energy Mater.

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Sodium ion capacitors (SICs) have drawn enormous interest due to their cost efficiency, superb power/energy densities, and long-span service life. Nevertheless, the imbalance of two involved electrodes in both kinetics and stability, mainly originating from battery-type anodes, restricts their practical application. Herein, we first propose a heterointerface engineering strategy to design a flexible self-supporting hybrid film anode, where metallic Mo 2 C quantum dots (QDs, ∼41.1 wt %) selfencapsulated in N-doped carbon nanofibers (N-CNFs) thanks to the interfacial interactions, toward advanced SICs. The synergistic effect of structural/compositional merits is highlighted with the induced interface coupling Mo−N−C toward enhanced electrochemical kinetics/stability and reinforced electrode structural integrity. The accelerating mechanism of electron migration at the heterogeneous interfaces is unveiled with density functional theory calculations. The obtained Mo 2 C QDs@N-CNFs film electrode is rendered with a competitive capacity of ∼160.9 mAh g −1 at 5.0 A g −1 , robust pseudocapacitive contribution, and long-duration cycling stability. Besides, the Mo 2 C QDs@N-CNFs-based SICs exhibit exceptional electrochemical properties. More significantly, the in-depth insights into the unique Na + -(de)intercalation mechanism of Mo 2 C QDs@N-CNFs are rationally proposed with in situ X-ray diffraction and electrochemical techniques. This promises the enormous potential of our designed carbon-matrix-confined Mo 2 C QDs nanohybrid for SICs and beyond.

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Configurational correlations in the coverage dependent adsorption energies of oxygen atoms on late transition metal fcc(111) surfaces

Miller

İnoğlu

Kitchin

2011

The Journal of Chemical Physics

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The coverage dependence of oxygen adsorption energies on the fcc(111) surfaces of seven different transition metals (Rh, Ir, Pd, Pt, Cu, Au, and Ag) is demonstrated through density functional theory calculations on 20 configurations ranging from one to five adsorption sites and coverages up to 1 ML. Atom projected densities of states are used to demonstrate that the d-band mediated adsorption mechanism is responsible for the coverage dependence of the adsorption energies. This common bonding mechanism results in a linear correlation that relates the adsorption energies of each adsorbate configuration across different metal surfaces to each other. The slope of this correlation is shown to be related to the characteristics of the valence d-orbitals and band structure of the surface metal atoms. Additionally, it is shown that geometric similarity of the configurations is essential to observe the configurational correlations.

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Substrate-Mediated Interaction on Ag(111) Surfaces from First Principles

Cited by 3 publications

References 28 publications

On the Stability of Ag/Au(111) Expanded Structures

On the Stability of Ag/Au(111) Expanded Structures

Metallic Mo₂C Quantum Dots Confined in Functional Carbon Nanofiber Films toward Efficient Sodium Storage: Heterogeneous Interface Engineering and Charge-Storage Mechanism

Configurational correlations in the coverage dependent adsorption energies of oxygen atoms on late transition metal fcc(111) surfaces

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Substrate-Mediated Interaction on Ag(111) Surfaces from First Principles

Cited by 3 publications

References 28 publications

On the Stability of Ag/Au(111) Expanded Structures

On the Stability of Ag/Au(111) Expanded Structures

Metallic Mo2C Quantum Dots Confined in Functional Carbon Nanofiber Films toward Efficient Sodium Storage: Heterogeneous Interface Engineering and Charge-Storage Mechanism

Configurational correlations in the coverage dependent adsorption energies of oxygen atoms on late transition metal fcc(111) surfaces

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Metallic Mo₂C Quantum Dots Confined in Functional Carbon Nanofiber Films toward Efficient Sodium Storage: Heterogeneous Interface Engineering and Charge-Storage Mechanism