Origins of Nanoscale Heterogeneity in Ultrathin Films

Hannon, James B.; Sun, Jiebing; Pohl, Karsten; Kellogg, G. L.

doi:10.1103/physrevlett.96.246103

Cited by 50 publications

(54 citation statements)

References 15 publications

(17 reference statements)

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“…In the present case, the spatial resolution during the I(V ) measurement has been determined to 9.0 nm using the established 20%-80% criterion, which is seen to essentially translate into the fingerprinting analysis. Together with the work of Hannon and coworkers, who published a comparable value for an analysis performed of a bimetallic surface alloy [23], this is the highest spatial resolution achieved in I(V )-LEEM fingerprinting to date.…”

Section: Mapping Of Surface Components By Twodimensional I(v )-Leem Amentioning

confidence: 99%

Nanoscale analysis of the oxidation state and surface termination of praseodymium oxide ultrathin films on ruthenium(0001)

et al. 2017

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Section: Mapping Of Surface Components By Twodimensional I(v )-Leem Amentioning

confidence: 99%

Nanoscale analysis of the oxidation state and surface termination of praseodymium oxide ultrathin films on ruthenium(0001)

et al. 2017

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“…We prepare the Cu(001)-c(2 × 2)-Pd buried surface alloy by depositing Pd (5 ML/hour) from an e-beam heated wire source onto the sample held at 210 • C. The structure, and growth, of the c(2 × 2)-Pd alloy are well understood. [10][11][12][13][14][15]20 The buried alloy forms when submonolayer coverages of Pd are deposited on Cu(001) at T> 150 • C. On terraces, Fig. 1 (a), the alloy consists of a c(2 × 2)-ordered Pd-Cu underlayer covered by a relatively pure layer of Cu.…”

Section: Experiments a Methods And Materialsmentioning

confidence: 99%

“…spatial variations in Pd concentration, or compositional changes at the surface during island ripening measurements. 14,15,22 Fig . 2 shows images of the surface alloy (0.4 ML Pd) with epitaxial Cu adatom islands.…”

Section: B Leem Characterization Of the Surface Alloymentioning

confidence: 99%

“…1. 14,15 In an I-V measurement, specular LEEM images are recorded versus the energy of the incident electrons. The energy-dependent electron reflectivity is sensitive to the surface structure to a depth of several atomic layers.…”

Section: B Leem Characterization Of the Surface Alloymentioning

confidence: 99%

“…9 In the Cu(001)-c(2×2)-Pd buried surface alloy system, the Pd alloy is covered by a nearly pure layer of copper. [10][11][12][13][14][15] It is not evident that the buried Pd will have a significant influence on surface mass transport. In this work, we use Cu-adatom island-ripening measurements to show that Cu(001) surface diffusion is slowed by the presence of buried Pd atoms near the surface.…”

Section: Introductionmentioning

confidence: 99%

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Buried Pd slows self-diffusion on Cu(001)

et al. 2011

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Using low-energy electron microscopy, we determine that self-diffusion of the Cu(001) surface is slowed by the presence of a c(2 × 2)-Pd buried surface alloy. We probe surface diffusion using Cu-adatom island-ripening measurements. On alloyed surfaces, the island decay rate decreases monotonically as the Pd concentration is increased up to ∼ 0.5 ML, where the 2 × 2 buried alloy is Pd saturated. We propose that the Pd slows island ripening by inhibiting the diffusion of surface vacancies across terraces. For dilute alloys ( < ∼ 0.2 ML Pd), this conclusion is supported by densityfunctional theory calculations which show that surface vacancies migrate more slowly owing to an attraction to isolated buried Pd atoms. The results illustrate a fundamental mechanism by which even a dilute alloy thin-film coating may act to inhibit surface-diffusion-mediated processes, such as electromigration.

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Low‐Energy Electron Microscopy

Flege

Tang

Altman

2012

Characterization of Materials

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Low‐energy electron microscopy (LEEM) is a powerful method to study solid surfaces, thin films, and other surface‐supported nanostructures. Among the assorted electron‐based microscopies that are available, LEEM stands out for its strong surface sensitivity, real‐time imaging capability, and a number of unique contrast mechanisms that exploit the wave nature of imaging electrons. Furthermore, the capability to provide complementary reciprocal space information on a very small length scale using micro‐low energy electron diffraction in a LEEM brings many added strengths. LEEM is an ultrahigh vacuum technique, in which numerous approaches to in situ surface modification can be performed during imaging. These capabilities allow the study of structure, morphology and dynamic processes with excellent spatial and temporal resolution.

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Origins of Nanoscale Heterogeneity in Ultrathin Films

Cited by 50 publications

References 15 publications

Nanoscale analysis of the oxidation state and surface termination of praseodymium oxide ultrathin films on ruthenium(0001)

Nanoscale analysis of the oxidation state and surface termination of praseodymium oxide ultrathin films on ruthenium(0001)

Buried Pd slows self-diffusion on Cu(001)

Low‐Energy Electron Microscopy

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