Effects of thickness on the cation segregation in epitaxial (001) and (110) La2/3Ca1/3MnO3 thin films

Estradé, S.; Rebled, J. M.; Arbiol, Jordi; Peiró, Francesca; Infante, I. C.; Herranz, G.; Sánchez, F.; Fontcuberta, J.; Córdoba, R.; Mendis, Budhika G.; Bleloch, Andrew

doi:10.1063/1.3211130

Cited by 47 publications

(40 citation statements)

References 15 publications

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“…This deviation points to a slight oxygen deficiency in these films 55,56 and is attributed to the beneficial effect of the formation of oxygen vacancies in order to reduce the lattice mismatch for films which grow under tensile lattice strain. 57 Partially relaxed films on ReScO 3 with Re 5 Dy, Tb, Gd PFM data in Figs. 5(a)-5(c) show that domain formation critically depends on the magnitude of lattice mismatch.…”

Section: Partially Relaxed Films On Ndgaomentioning

confidence: 99%

Ferroelectric domain structure of anisotropically strained NaNbO3 epitaxial thin films

Schwarzkopf

Braun

Schmidbauer

et al. 2014

Journal of Applied Physics

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NaNbO3 thin films have been grown under anisotropic biaxial strain on several oxide substrates by liquid-delivery spin metalorganic chemical vapor deposition. Compressive lattice strain of different magnitude, induced by the deposition of NaNbO3 films with varying film thickness on NdGaO3 single crystalline substrates, leads to modifications of film orientation and phase symmetry, which are similar to the phase transitions in Pb-containing oxides near the morphotropic phase boundary. Piezoresponse force microscopy measurements exhibit large out-of-plane polarization components, but no distinctive domain structure, while C-V measurements indicate relaxor properties in these films. When tensile strain is provoked by the epitaxial growth on DyScO3, TbScO3, and GdScO3 single crystalline substrates, NaNbO3 films behave rather like a normal ferroelectric. The application of these rare-earth scandate substrates yields well-ordered ferroelectric stripe domains of the type a1/a2 with coherent domain walls aligned along the [001] substrate direction as long as the films are fully strained. With increasing plastic lattice relaxation, initially, a 2D domain pattern with still exclusively in-plane electric polarization, and finally, domains with in-plane and out-of-plane polar components evolve.

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Section: Partially Relaxed Films On Ndgaomentioning

confidence: 99%

Ferroelectric domain structure of anisotropically strained NaNbO3 epitaxial thin films

Schwarzkopf

Braun

Schmidbauer

et al. 2014

Journal of Applied Physics

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“…40, 41 An increase in Fe content may make it easier to equilibrate a larger amount of (positively charged) oxygen vacancies near the surface that electrostatically prefers Sr 2+ ions more than the Ti 4+ or Fe 3+/4+ ions. Second is the elastic interactions related to large size of Sr, which can drive the Sr to 20 free surfaces to minimize the elastic energy of the system 42,43 (note that the lattice parameter of STF decreases with increasing Fe content 18 ). In the authors' ongoing research, these driving forces for cation segregation phenomenon are being assessed quantitatively using both experiments and computation.…”

Section: Surface Chemical Composition and The Binding Environment Of Srmentioning

confidence: 99%

Impact of Sr segregation on the electronic structure and oxygen reduction activity of SrTi1−xFexO3 surfaces

Chen

Jung

Cai

et al. 2012

Energy Environ. Sci.

198

180

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The correlation between the surface chemistry and electronic structure is studied for SrTi 1-x Fe x O 3 (STF), as a model perovskite system, to explain the impact of Sr segregation on the oxygen reduction activity of cathodes in solid oxide fuel cells. Dense thin films of SrTi 0.95 Fe 0.05 O 3 (STF5), SrTi 0.65 Fe 0.35 O 3 (STF35) and SrFeO 3 (STF100) were investigated using a coordinated combination of surface probes. Composition, chemical binding, and valence band structure analysis using angle-resolved x-ray photoelectron 10 spectroscopy showed that Sr enrichment increases on the STF film surfaces with increasing Fe content. In situ scanning tunnelling microscopy / spectroscopy results proved the important and detrimental impact of this cation segregation on the surface electronic structure at high temperature and in oxygen environment. While no apparent band gap was found on the STF5 surface due to defect states at 345 o C and 10 -3 mbar of oxygen, the surface band gap increased with Fe content, 2.5 ± 0.5 eV for STF35 and 3.6 ± 0.6 eV for 15 STF100, driven by a down-shift in energy of the valence band. This trend is opposite to the dependence of the bulk STF band gap on Fe fraction, and is attributed to the formation of a Sr-rich surface phase in the form of SrO x on the basis of the measured surface band structure. The results demonstrate that Sr segregation on STF can deteriorate oxygen reduction kinetics through two mechanisms -inhibition of electron transfer from bulk STF to oxygen species adsorbing onto the surface, and the smaller 20 concentration of oxygen vacancies available on the surface for incorporating oxygen into the lattice. IntroductionBecause of their high efficiency and fuel flexibility, solid oxide fuel cells (SOFCs) offer the potential to contribute significantly to a clean energy infrastructure 1, 2 . However, their high working 25 temperatures (>800 o C) impose challenges due to accelerated materials degradation and high cost. The lowering of the working temperature has, therefore, become a strong focus of research. 3 At reduced temperatures (<700 o C), slow Oxygen Reduction Reaction (ORR) kinetics at the cathode become a major barrier to 30 the implementation of high performance SOFCs. To rationally design new cathode materials with high ORR activity, it is necessary to understand the governing ORR mechanisms and identify key descriptors of the cathode materials that directly control ORR activity. The strength of oxygen adsorption and the 35 energy barriers to oxygen dissociation, reduction and incorporation are believed to be the processes that determine oxygen reduction activity on perovskite oxides. 4,5 The energetics of these processes depends, in part, on the cathode electronic structure. In transition metal catalysis, the d-40 band structure 6 is a well-established descriptor of ORR activity. However, the applicability of the d-band model to perovskite oxide SOFC cathodes is limited by their complex surface chemistry (an anion and two cation sublattices), the role of oxygen vacan...

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“…In our recent work, we showed that cation segregation can be described by the elastic and electrostatic interactions of the dopant with the surrounding lattice in perovskite oxides. (1) The specific mechanisms include the size mismatch between the dopant and host cations and the associated elastic energy minimization by pushing the dopant to free surfaces or interfaces (18)(19)(20)(21), and the charged defect interactions, such as a strong association of dopant cations with oxygen vacancies, which can drive the dopants to positively charged interfaces where oxygen vacancies are in abundance (22) as well as with polar surfaces. Based on this understanding, we propose that deficiency of the A-site cations on the perovskite lattice should suppress the dopant segregation on the A-site by allowing for more space in the bulk and reducing the elastic energy.…”

Section: Introductionmentioning

confidence: 99%

Factors that Influence Cation Segregation at the Surfaces of Perovskite Oxides

Lee

Yildiz

2013

ECS Trans.

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As the oxygen reduction reaction (ORR) becomes more critical for development of solid oxide fuel cells (SOFCs) that operate at 500-700 C, the correlation between the surface chemistry and electrochemical performance is important to understand and enable design of cathode materials with optimal surface chemistry. Recently we demonstrated that elastic and electrostatic interactions of the dopant with the host lattice drive dopant segregation, a detrimental process on the surface of perovskite cathodes (1). Motivated by those results, here we investigated the effects of Asite stoichiometry in La 0.8 Sr 0.2 MnO 3 (LSM) thin films on the surface chemistry and electrochemical activity. Angle-resolved Xray photoelectron spectroscopy was employed to identify the surface cation content and chemical bonding states. A-site deficient LSM films showed higher chemical stability against Sr segregation and secondary phase formation upon annealing. This was correlated with a higher electrochemical activity measured by AC impedance spectroscopy. Given the insulating nature of secondary phases created on the surface upon annealing, observed higher electrochemical stability in A-site deficient LSM films can be ascribed to the suppressed surface segregation and phase separation.

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Effects of thickness on the cation segregation in epitaxial (001) and (110) La2/3Ca1/3MnO3 thin films

Cited by 47 publications

References 15 publications

Ferroelectric domain structure of anisotropically strained NaNbO3 epitaxial thin films

Ferroelectric domain structure of anisotropically strained NaNbO3 epitaxial thin films

Impact of Sr segregation on the electronic structure and oxygen reduction activity of SrTi1−xFexO3 surfaces

Factors that Influence Cation Segregation at the Surfaces of Perovskite Oxides

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