Dielectric properties of ferroelectric thin films with surface transition layers

Chen, Hui; Lü, Tianquan; Cui, Lian; Cao, Wenwu

doi:10.1016/j.physa.2007.10.070

Cited by 7 publications

(3 citation statements)

References 39 publications

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“…where ε0 the permittivity of free space, εr dielectric constant of the insulating film, A the area and d the thickness) and loss tangent (𝑡𝑎𝑛𝛿 =    ) was obtained directly from the measurement [9]. The variation of ɛ and tanδ as a function of temperature at different frequencies is shown in the Figure 4.…”

Section: Dielectric Propertiesmentioning

confidence: 99%

Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties

Bhasker

Sharma

Kumar

et al. 2022

J. Phys.: Conf. Ser.

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The Pb(Zr0.5, Ti0.5)O3 (PZT) is one of the ferroelectric materials used in the non-volatile memories. However, PZT usually suffers from fatigue that degrades the polarization with metallic electrodes. The high stability associated with Sr-O bonding reduces oxygen vacancies which in turn lessens fatigue and hence Sr in introduced at Pb site. In the present study (Pb0.65Sr0.35)(Zr0.5, Ti0.5)O3 (PSZT) ferroelectric thin films were successfully prepared by sol-gel method. The structural and morphological properties of the thin film were studied by x-ray diffraction and atomic force microscopy, respectively. The crystallization of the film was completed at 600°C of annealing and the root mean square roughness of the 300 nm film was around 4.5 nm. When Pb in Pb(Zr0.5, Ti0.5)O3 was substituted with 35% Sr, the coercive field increased and the remnant polarization reduced as compared to pure PZT. The films were ferroelectric at room temperature with the phase transition temperature at ~375°K. The dielectric constant and the loss tangent at room temperature were 257 and 0.023, respectively at 100 kHz.

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Section: Dielectric Propertiesmentioning

confidence: 99%

Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties

Bhasker

Sharma

Kumar

et al. 2022

J. Phys.: Conf. Ser.

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“…Many theoretical studies have been performed (see e.g. [4][5][6]) where the common merit is the elucidation of the physical properties of ferroelectric materials: investigation of the phase transition mechanisms, physical characteristics and associated peculiarities, explanation of their microscopic origin and nature, and further explanation of other effects such as surface, size, doping, substrate defect effects and bulk behavior [38][39][40][41][42][43][44]. Even though many consistent microscopic theories, interpreting the observed phenomena in terms of microscopic models and atomic interactions, studying the behavior of thermodynamic quantities and clarifying the character of anomalies at the critical points, have been developed, a careful theoretical modeling of the properties of ferroelectrics that helps in the replication/analysis of ferroelectric phase transitions within a single model parameters approach has not yet been developed.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic properties of a quasi-harmonic model for ferroelectric transitions

Tchouobiap

Mashiyama

2011

J. Phys.: Condens. Matter

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Within a framework of a quasi-harmonic model for quantum particles in a local potential of the double Morse type and within the mean-field approximation for interactions between particles, we investigate the thermodynamic properties of ferroelectric materials. A quantum thermodynamic treatment gives analytic expressions for the internal energy, the entropy, the specific heat, and the static susceptibility. The calculated thermodynamic characteristics are studied as a function of temperature and energy barrier, where it is shown that at the proper choice of the theory parameters, particularly the energy barrier, the model system exhibits characteristic features of either second-order tricritical or first-order phase transitions. Our results indicate that the barrier energy seems to be an important criterion for the character of the structural phase transition. The influence of quantum fluctuations manifested on zero-point energy on the phase transition and thermodynamic properties is analyzed and discussed. This leads to several quantum effects, including the existence of a saturation regime at low temperatures, where the order parameter saturates giving thermodynamic saturation of the calculated thermodynamic quantities. It is found that both quantum effects and energy barrier magnitude have an important influence on the thermodynamic properties of the ferroelectric materials and on driving the phase transition at low temperatures. Also, the analytical parameters' effect on the transition temperature is discussed, which seems to give a general insight into the structural phase transition and its nature.

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“…[23][24][25][26] Considering the multilayer structures of surface layers, we have introduced a different film design to describe the STL in Ref. 27, which investigates the role of the intra-layer (within layer) and inter-layer (across layers) interactions (J a (m) and J e (m) as shown in Fig. 1) between two pseudo-spins in the formation of dielectric properties of ferroelectric thin films.…”

Section: Introductionmentioning

confidence: 99%

Polarization Properties of Ferroelectric Thin Films Under Different Boundary Conditions

et al. 2009

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By taking into account two types of boundary conditions (BC), free boundary condition (FBC) and zero boundary condition (ZBC), an improved transverse Ising model with the consideration of surface transition layers (STL) is used to describe the polarization properties of ferroelectric thin films in the framework of the mean field approximation. Functions representing the intralayer and inter-layer couplings are introduced to characterize the BC and STL, which reflect the structure variation of film surface. Comparing the results obtained by employing FBC and ZBC, some effects of BC are derived in the model, which demonstrated that the BC play important roles on the properties of ferroelectric thin films. It is shown that the effect of ZBC can extend to deeper film than that of FBC. When different BC are adopted, competition between the fields (depolarization field and transverse field) and BC induces some different and interesting phenomena. Some theoretical results in this paper are found to be in reasonable accordance with experimental data and have some application importance.

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Dielectric properties of ferroelectric thin films with surface transition layers

Cited by 7 publications

References 39 publications

Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties

Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties

Thermodynamic properties of a quasi-harmonic model for ferroelectric transitions

Polarization Properties of Ferroelectric Thin Films Under Different Boundary Conditions

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Dielectric properties of ferroelectric thin films with surface transition layers

Cited by 7 publications

References 39 publications

Sol-gel Derived (Pb0.65Sr0.35)(Zr0.5, Ti0.5)O3 Ferroelectric Thin Films: Structural and Electrical Properties

Sol-gel Derived (Pb0.65Sr0.35)(Zr0.5, Ti0.5)O3 Ferroelectric Thin Films: Structural and Electrical Properties

Thermodynamic properties of a quasi-harmonic model for ferroelectric transitions

Polarization Properties of Ferroelectric Thin Films Under Different Boundary Conditions

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Product

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Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties

Sol-gel Derived (Pb_0.65Sr_0.35)(Zr_0.5, Ti_0.5)O₃ Ferroelectric Thin Films: Structural and Electrical Properties