Stability of the Surface Electron Accumulation Layers on the Nonpolar (101̅0) and (112̅0) Faces of ZnO

Heinhold, Robert; Cooil, Simon; Evans, D. Andrew; Allen, Martin W.

doi:10.1021/jp507820m

Cited by 34 publications

(81 citation statements)

References 46 publications

(152 reference statements)

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“…Previous ZnO(1010) studies have focused on surfaces with H adsorbed either exclusively on surface O sites, 17 or have used comparably high H dosages that lead to a saturation of all energetically possible surface sites, 17,18,28 These studies do therefore not investigate the competition of H adsorption at the two different sites, especially in the regime of low coverages. Although the different effects of O-H vs. Zn-H bond formation have been recognized previously, a detailed microscopic view of how single H atoms interact with the pristine or slightly Hcovered ZnO(1010) surface is not established.…”

Section: -19mentioning

confidence: 99%

Local aspects of hydrogen-induced metallization of theZnO(101¯0)surface

et al. 2015

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This study combines surface-sensitive photoemission experiments with density functional theory (DFT) to give a microscopic description of H adsorption-induced modifications of the ZnO(1010) surface electronic structure. We find a complex adsorption behavior caused by a strong coverage dependence of the H adsorption energies: Initially, O-H bond formation is energetically favorable and H acting as an electron donor leads to the formation of a charge accumulation layer and to surface metallization. The increase of the number of O-H bonds leads to a reversal in adsorption energies such that Zn-H bonds become favored at sites close to existing O-H bonds, which results in a gradual extenuation of the metallization. The corresponding surface potential changes are localized within a few nanometers both laterally and normal to the surface. This localized character is experimentally corroborated by using sub-surface bound excitons at the ZnO(1010) surface as a local probe. The pronounced and comparably localized effect of small amounts of hydrogen at this surface strongly suggests metallic character of ZnO surfaces under technologically relevant conditions and may, thus, be of high importance for energy level alignment at ZnO-based junctions in general.

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Section: -19mentioning

confidence: 99%

Local aspects of hydrogen-induced metallization of theZnO(101¯0)surface

et al. 2015

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“…The increase in carrier concentration in the accumulation layer was correlated (i) to a variation of the band bending that induces quasi-bidimensional confined trapped states 29,[33][34][35][36]42 and (ii) to a decrease in work function. These adsorbate-dependent 43 evolutions of the band levels were characterized by optical measurements 5 , macroscopic 6,44 or local Kelvin probes 45 , ultraviolet 43,46 , laboratory X-ray 40,41,[47][48][49] or synchrotron [34][35][36]41,42 photoemission. Atomic H adsorption systematically diminishes the work function, bends bands downward to create an accumulation layer 6,[33][34][35][36]42 by creating H-related levels that donate electrons to the conduction band.…”

Section: Introductionmentioning

confidence: 99%

“…The origin of this accumulation/depletion zone has been intensively revisited in the past years through photoemission spectroscopy [34][35][36][40][41][42]48,49 .…”

Section: Introductionmentioning

confidence: 99%

“…The upward band bending of ZnO-Zn was more resilient to annealing. However, these studies 41,48,49 were performed on just cleaned as-loaded surfaces that kept inherent polishing damages and showed poor Low-Energy Electron Diffraction (LEED) patterns. Generally speaking, the origin of the observed changes in work function, band bending and conductivity remains unclear although there are compelling evidence of a correlation with surface hydroxylation; surface states 53,54 , donor characters of surface hydroxyl groups [34][35][36][40][41][42]45,48,49 , hydrogen diffusion in the subsurface, subsurface defects diffusion 6,43 have all been invoked.…”

Section: Introductionmentioning

confidence: 99%

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Band alignment at Ag/ZnO(0001) interfaces: A combined soft and hard x-ray photoemission study

et al. 2018

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Band alignment at the interface between evaporated silver films and Zn-or O-terminated polar orientations of ZnO is explored by combining soft and hard X-ray photoemissions on native and hydrogenated surfaces. Ultraviolet Photoemission Spectroscopy (UPS) is used to track variations of work function, band bending, ionization energy and Schottky barrier during silver deposition.The absolute values of band bending and the bulk position of the Fermi level are determined on continuous silver films by HArd X-ray PhotoEmission Spectroscopy (HAXPES) through a dedicated modeling of core levels. Hydrogenation leads to the formation of ∼ 0.3 monolayer of donor-like hydroxyl groups on both ZnO-O and ZnO-Zn surfaces and to the release of metallic zinc on ZnO-Zn. However no transition to an accumulation layer is observed. On bare surfaces, silver adsorption is cationic on ZnO(0001)-O (anionic on ZnO(0001)-Zn) at the earliest stages of growth as expected from polarity healing before adsorbing as a neutral species. UPS and HAXPES data appear quite consistent. The two surfaces undergo rather similar band bendings for all types of preparation. The downward band bending of V bb,ZnO−O = −0.4 eV and V bb,ZnO−Zn = −0.6 eV found for the bare surfaces are reinforced for upon hydrogenation (V bb,ZnO−O+H = −1.1 eV, V bb,ZnO−Zn+H = −1.2 eV). At the interface with Ag, a unique value of band bending of -0.75 eV is observed. While exposure to atomic hydrogen modulates strongly the energetic positions of the surface levels, a similar Schottky barrier of 0.5-0.7 eV is found for thick silver films on the two surfaces.

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“…The plots (b) and (c) show the spatial distribution of the conduction band minimum energy (relative to the Fermi level) when there is an acceptor charge density of 1x10 12 cm -2 and donor charge of density 1x10 13 cm -2 , respectively.Although no surface charge was required to provide agreement between the simulated and experimental results here, the electrostatic condition of the semiconductor surface can affect the transport in nanostructures. This is highly debated for ZnO with many reports showing polar and non-polar ZnO facets in accumulation, while studies of large-area nanowire arrays show a generalized depletion [42][43][44]. The effect on the I-V characteristics of accumulation or depletion of the side and top surfaces of the nanowires is explored through simulations.…”

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confidence: 99%

Controlling the Electrical Transport Properties of Nanocontacts to Nanowires

Lord¹,

Maffeïs²,

Kryvchenkova³

et al. 2015

Nano Lett.

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The ability to control the properties of electrical contacts to nanostructures is essential to realize operational nanodevices. Here, we show that the electrical behavior of the nanocontacts between free-standing ZnO nanowires and the catalytic Au particle used for their growth can switch from Schottky to Ohmic depending on the size of the Au particles in relation to the cross-sectional width of the ZnO nanowires. We observe a distinct Schottky to Ohmic transition in transport behavior at an Au to nanowire diameter ratio of 0.6. The current-voltage electrical measurements performed with a multiprobe instrument are explained using 3-D self-consistent electrostatic and transport simulations revealing that tunneling at the contact edge is the dominant carrier transport mechanism for these nanoscale contacts. The results are applicable to other nanowire materials such as Si, GaAs, and InAs when the effects of surface charge and contact size are considered.

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Stability of the Surface Electron Accumulation Layers on the Nonpolar (101̅0) and (112̅0) Faces of ZnO

Cited by 34 publications

References 46 publications

Local aspects of hydrogen-induced metallization of theZnO(101¯0)surface

Local aspects of hydrogen-induced metallization of theZnO(101¯0)surface

Band alignment at Ag/ZnO(0001) interfaces: A combined soft and hard x-ray photoemission study

Controlling the Electrical Transport Properties of Nanocontacts to Nanowires

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