Oxygen diffusion in ultrafine grained monoclinic ZrO2

Brossmann, Ulrich; Würschum, Roland; Södervall, U.; Schaefer, H.‐E.

doi:10.1063/1.370567

Cited by 193 publications

(117 citation statements)

References 39 publications

(24 reference statements)

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“…The formation of structural defects upon cooling would, therefore, require the diffusion of cations and/or oxygen ions. Using the diffusion parameters of oxygen in nanocrystalline zirconia [128], Forker et al estimate oxygen jump rates [129] of the order of 10 -4 and 10 -1 s -1 for the core and the interfacial region, respectively, of nanocrystalline ZrO 2 at T~600 K, where the defect component starts to appear. The cation jump rates are even smaller.…”

Section: Defect and Diffusion Forum Vol 311mentioning

confidence: 99%

Impurity Centers in Oxides Investigated by γ-γ Perturbed Angular Correlation Spectroscopy and <i>Ab Initio</i> Calculations

Pasquevich

Rentería

2011

DDF

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Abstract. In this chapter Perturbed Angular Correlation (PAC) experiments on binary oxides are described. These experiments provide local-scale fingerprints about the formation, identification, and lattice environment of defect complexes at the PAC probe site. The potential of the PAC observations in conjunction with ab initio calculations is shown. Measurements of the electric-field gradient at impurity sites using 111 Cd and 181 Ta probes are reviewed. Special attention is paid to oxides with the bixbyite structure. The case of In 2 O 3 is particularly analyzed. Results obtained with HfO 2 , in form of coarse grain or nano particles, are described. The potential results that can be obtained from Density Functional Theory ab initio calculations in doped systems are shown describing the main results observed in many impurity-host systems.

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Section: Defect and Diffusion Forum Vol 311mentioning

confidence: 99%

Impurity Centers in Oxides Investigated by γ-γ Perturbed Angular Correlation Spectroscopy and <i>Ab Initio</i> Calculations

Pasquevich

Rentería

2011

DDF

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“…For example, the bulk diffusion length (~D v t ) of oxygen in monoclinic, nanocrystalline zirconia is much greater than the gate dielectric thickness at typical annealing times [23]. Grain boundary diffusion coefficients in nanocrystalline zirconia are orders of magnitude larger than bulk coefficients [23].…”

Section: B) Uncapped Anneals Under Conditions That Favor Reaction (1)mentioning

confidence: 99%

Thermodynamic considerations in the stability of binary oxides for alternative gate dielectrics in complementary metal–oxide–semiconductors

Stemmer¹

2004

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

110

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A number of binary oxides have been predicted to be thermodynamically stable in contact with Si and are candidates to replace SiO 2 in CMOS. However, reactions leading to the formation of interfacial silicide, silicate or SiO 2 layers have been reported when these oxides are exposed to high temperatures during device processing. Different pathways have been proposed in the literature to explain these reactions. In this paper, a thermodynamic analysis of the proposed reactions is performed. The analysis includes gaseous species, because typical gate dielectrics are ultra-thin layers and diffusivities for species from the surrounding atmosphere, such as oxygen, may be high. Furthermore, nonstoichiometry of the high-k oxide, as may be resulting from nonequilibrium deposition processes or reducing atmospheres during processing is also considered. Studies are proposed to distinguish between possible reaction mechanisms. Finally guidelines for stable interfaces are presented.3

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“…Oxygen self-diffusion in zirconium oxide has long been a topic of interest [1][2][3][4] in studying the oxidation kinetics of zirconium alloys, which are used as cladding of nuclear fuel in light water cooled nuclear reactors [5]. Zirconium oxide is also widely used in heterogeneous catalysis [6,7], and more recently it was examined for high-k dielectrics in metal-oxide-semiconductor field-effect transistor (MOSFET) devices [8,9] as well as resistive switching devices [10,11].…”

Section: Introductionmentioning

confidence: 99%

Oxygen self-diffusion mechanisms in monoclinic ZrO2 revealed and quantified by density functional theory, random walk analysis, and kinetic Monte Carlo calculations

2018

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In this work, we quantify oxygen self-diffusion in monoclinic-phase zirconium oxide as a function of temperature and oxygen partial pressure. A migration barrier of each type of oxygen defect was obtained by first-principles calculations. Random walk theory was used to quantify the diffusivities of oxygen interstitials by using the calculated migration barriers. Kinetic Monte Carlo simulations were used to calculate diffusivities of oxygen vacancies by distinguishing the threefold-and fourfold-coordinated lattice oxygen. By combining the equilibrium defect concentrations obtained in our previous work together with the herein calculated diffusivity of each defect species, we present the resulting oxygen self-diffusion coefficients and the corresponding atomistically resolved transport mechanisms. The predicted effective migration barriers and diffusion prefactors are in reasonable agreement with the experimentally reported values. This work provides insights into oxygen diffusion engineering in ZrO 2 -related devices and parametrization for continuum transport modeling.

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Oxygen diffusion in ultrafine grained monoclinic ZrO2

Cited by 193 publications

References 39 publications

Impurity Centers in Oxides Investigated by γ-γ Perturbed Angular Correlation Spectroscopy and <i>Ab Initio</i> Calculations

Impurity Centers in Oxides Investigated by γ-γ Perturbed Angular Correlation Spectroscopy and <i>Ab Initio</i> Calculations

Thermodynamic considerations in the stability of binary oxides for alternative gate dielectrics in complementary metal–oxide–semiconductors

Oxygen self-diffusion mechanisms in monoclinic ZrO2 revealed and quantified by density functional theory, random walk analysis, and kinetic Monte Carlo calculations

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