Re-distribution of oxygen at the interface between γ-Al2O3 and TiN

Filatova, E. O.; Konashuk, Aleksei S.; Sakhonenkov, Sergei S.; Sokolov, Andréy; Afanasʼev, Valeri

doi:10.1038/s41598-017-04804-4

Cited by 42 publications

(44 citation statements)

References 63 publications

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“…A mention on the influence of oxygen deficiency on dielectric breakdown is worthy at this point, since there is wide agreement on pinpointing oxygen vacancies as the defects that promote the formation and enlargement of the percolation path in the early stages of dielectric breakdown . The selection of the electrodes plays a crucial role on different nanoelectronics devices, as they act as oxygen scavengers for the oxide: on MIM structures, they help defining the performance figures of resistive switching devices and promoting the presence of dipoles and interfacial layers on the metal/dielectric interface that tune the energy barrier of the system; on MOS devices, the BD statistics can be affected by recovery of the BD path . This behavior can lead to the formation of a large amount of oxygen vacancies in the dielectric, which play a key role in the evolution of the BD path.…”

Section: Breakdown Of Gate Insulators For Cmos: Silicon Oxynitrides Amentioning

confidence: 99%

A Review on Dielectric Breakdown in Thin Dielectrics: Silicon Dioxide, High‐k, and Layered Dielectrics

Palumbo

Wen

Lombardo

et al. 2019

Adv Funct Materials

163

104

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Thin dielectric films are essential components of most micro-and nanoelectronic devices, and they have played a key role in the huge development that the semiconductor industry has experienced during the last 50 years. Guaranteeing the reliability of thin dielectric films has become more challenging, in light of strong demand from the market for improved performance in electronic devices. The degradation and breakdown of thin dielectrics under normal device operation has an enormous technological importance and thus it is widely investigated in traditional dielectrics (e.g., SiO 2 , HfO 2 , and Al 2 O 3 ), and it should be further investigated in novel dielectric materials that might be used in future devices (e.g., layered dielectrics). Understanding not only the physical phenomena behind dielectric breakdown but also its statistics is crucial to ensure the reliability of modern and future electronic devices, and it can also be cleverly used for other applications, such as the fabrication of new-concept resistive switching devices (e.g., nonvolatile memories and electronic synapses). Here, the fundamentals of the dielectric breakdown phenomenon in traditional and future thin dielectrics are revised. The physical phenomena that trigger the onset, structural damage, breakdown statistics, device reliability, technological implications, and perspectives are described.

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Section: Breakdown Of Gate Insulators For Cmos: Silicon Oxynitrides Amentioning

confidence: 99%

A Review on Dielectric Breakdown in Thin Dielectrics: Silicon Dioxide, High‐k, and Layered Dielectrics

Palumbo

Wen

Lombardo

et al. 2019

Adv Funct Materials

163

104

View full text Add to dashboard Cite

show abstract

“…There is, however, a well detectable (≈200 meV) difference between the IPE thresholds of the top and bottom electrodes. This asymmetry may be caused by a different oxygen distribution at the two interfaces since the observed incorporation of oxygen in the near‐interface layer of the top TiN electrode suggests partial oxidation of TiN as a result of oxygen scavenging from γ‐Al 2 O 3 . What is interesting, however, is the EWF of TiN evaluated from the observed 3.0 and 3.2 eV interface barriers (Figure ) taking into account a ≈ 0.5 eV upshift of the CB bottom in γ‐Al 2 O 3 as compared to the as‐deposited amorphous ALD‐alumina .…”

Section: Effective Workfunction and Inhomogeneous Barriersmentioning

confidence: 99%

Internal Photoemission Metrology of Inhomogeneous Interface Barriers

Afanas’ev

Kolomiiets

Houssa

et al. 2017

Physica Status Solidi (a)

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Interfaces of heterogeneous solids, ranging from polycrystalline materials to composites, are frequently encountered in nanotechnology. Electron transport in these materials and across their interfaces critically depends on the energy barriers electrons encounter on their way. Because of electrode structural heterogeneity, the barriers may exhibit significant spatial variations resulting in a broad distribution of barrier heights and built-in potentials. Quantification of the distributed interface barriers represents a formidable experimental challenge since direct association of interface properties with those of an outer free surface is generally inaccurate. Here we present a methodology enabling quantification of electron barriers at interfaces of semiconductors and metals with insulators using the electric field-dependent internal photoemission (IPE) of electrons. It is shown that practically relevant interfaces may contain "patches" with differences in barrier height (or the effective work function) of up to 1 eV, which makes the electrode heterogeneity a crucial factor in designing electron devices suitable for low-voltage operation.

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“…This agrees with prior experiments that argue that the O K-edge is largely due to excitation of O 1s electrons into unoccupied O 2p states hybridized with the orbitals of the bonding atom. 20,25,[64][65][66][67] Our pDOS calculations provide some further detail, indicating that peak B is largely O*(2s)-Al(3s), peak D arguably O*(2s)-Al(3d), although peak C may be a complicated mixture with Al 3p and 3d states. However, no bands match peak A.…”

Section: Benchmarking Al O and Na K-edge Xanes Spectramentioning

confidence: 75%

“…S2, ESI †) and are most likely either epoxide transitions or, less likely, defects/vacancies from beam damage 25 or oxygen scavenging. 65 Most importantly, one of the primary edge features (A) is not reproduced. Experimental spectra show three distinct peaks, A-C, with a shoulder D. The theoretical spectrum shows three peaks, tentatively ascribed as peaks B-D although this is ambiguous.…”

Section: Benchmarking Al O and Na K-edge Xanes Spectramentioning

confidence: 99%

Probing hydrogen bonding interactions and impurity intercalation in gibbsite using experimental and theoretical XANES spectroscopy

McIntosh

Chan

2018

Phys. Chem. Chem. Phys.

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The Al and O K-edge XANES spectra of Bayer process gibbsite are examined, both experimentally and with plane wave density functional theory, and transition assignments are made. We confirm that the broad transitions in Al K-edge spectra are fundamentally the same as those in more ordered and well-studied corundum, and typical of octahedrally coordinated aluminium. Analysis of O K-edge spectra reveals that while much of the initial edge transition structure (535-548 eV) is due to O 2p hybridization with Al orbitals, the lowest energy region (∼535-539 eV) is particularly influenced by O-H states which are heavily perturbed by hydrogen bonding interactions. We therefore tentatively suggest that an unexplained structure at 539 eV in O K-edge spectra of corundum may be due to surface hydroxylation. Finally, we examined Na K-edge spectra, as sodium is the major impurity in these materials and implicated in perturbation of the evolution of materials properties with calcination through the transition aluminas. Density functional theory calculations find sodium replacement of in-sheet H-atoms is the most thermodynamically stable site for sodium inclusion. We subsequently confirm this assignment spectroscopically, explicitly demonstrating the precise location of Na+ impurities for the first time.

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Re-distribution of oxygen at the interface between γ-Al2O3 and TiN

Cited by 42 publications

References 63 publications

A Review on Dielectric Breakdown in Thin Dielectrics: Silicon Dioxide, High‐k, and Layered Dielectrics

A Review on Dielectric Breakdown in Thin Dielectrics: Silicon Dioxide, High‐k, and Layered Dielectrics

Internal Photoemission Metrology of Inhomogeneous Interface Barriers

Probing hydrogen bonding interactions and impurity intercalation in gibbsite using experimental and theoretical XANES spectroscopy

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