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Dielectric properties of BT-LMT mixed ceramics Povilas Keburis1, Juras Banys1, Algirdas Brilingas1, Jonas Grigas1, Andrei Salak2, and Victor M. Ferreira3.

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Presentation on theme: "Dielectric properties of BT-LMT mixed ceramics Povilas Keburis1, Juras Banys1, Algirdas Brilingas1, Jonas Grigas1, Andrei Salak2, and Victor M. Ferreira3."— Presentation transcript:

1 Dielectric properties of BT-LMT mixed ceramics Povilas Keburis1, Juras Banys1, Algirdas Brilingas1, Jonas Grigas1, Andrei Salak2, and Victor M. Ferreira3 1Department of Radiophysics, Vilnius University, Lithuania 2Department of Ceramics and Glass Engineering/CICECO, University of Aveiro, Portugal 3Department of Civil Engineering/CICECO, University of Aveiro, Aveiro, Portugal

2 BT-LMT (1-x)BaTiO3-x La(Mg1/2Ti1/2O3) BT ferroelectric,
LMT non-ferroelectric, Homo- and heterovalent substitutions suppress FE PT in BT and induce relaxor behavior. The continuous crossover from FE to relaxor behavior. X = 2.5% of LMT: ferroelectric & relaxor features. Lead free perovskites for microwave applications. A.N.Salak, M.P.Seabra, V.M.Ferreira, J.Am.Ceram.Soc. 87, 216 (2004) A.N.Salak, M.P.Seabra, V.M.Ferreira et al. J.Phys.D: Appl. Phys. 37, 914 (2004) A.N.Salak, V.V.Shvartsman, M.P.Seabra, A.L.Kholkin, V.M.Ferreira, J.Phys.:Condens. Matter 16, 2785 (2004).

3 Relaxation times distribution
The aim? Relaxation times distribution of polar (nano)clusters.

4 Comparison of the temperature dependences of the real part of dielectric permittivity of homogenous and non-homogenous ceramics 2.5%LMT-BT

5 Temperature dependence of the real and imaginary parts of dielectric permittivity at different frequencies of 2.5%LMT – BT (homogenous).

6 Frequency dependence of the real and imaginary parts of permittivity of 2.5%LMT – BT (homogenous).

7 Frequency dependence of the real and imaginary parts of permittivity measured in different temperatures fitted with Debye

8 Real distribution of relaxation times
The original program performs the direct calculation of relaxation times distribution function g() from the frequency dependence of the complex dielectric permittivity at fixed temperatures according to superposition of the Debye‑like processes: .    (1) The basic integral transformations (1) can be presented as the following linear matrix equation: AX = T, (2) matrix A components are obtained by proper discretization of the integral transformation kernels, vectors T and X components correspond discretized values of the permittivity and distribution of relaxation times, respectively. Equation (3) is the ill-posed problem, and cannot be solved straightforwardly. It is replaced by the following minimization problem:  = ||T ‑ AX || +  ||RX||, (3)  is the regularization parameter, R is the regularization matrix, which corresponds to the second g"() derivative. This constrained regularized minimization problem is solved by least squares technique.

9 Distribution of the relaxation times of BT – 2.5%LMT (homogenous)

10 Temperature dependence of the real and imaginary parts of permittivity at of BT – 2.5%LMT (non-homogenous).

11 Frequency dependence of the real and imaginary parts of dielectric permittivity. Lines are the best fits with the obtained distribution of the relaxation times

12 . Distribution of the relaxation times of 2.5%LMT – BT (non-homogenous)

13 C o n c l u s i o n s 1. BT – 2.5%LMT ceramics exhibit both ferroelectric & relaxor behavior Dynamics of polar nanoclusters cause dielectric dispersion and losses in wide frequency range below the phonon frequencies.

14 Thanks for your attention

15 Students of Vilnius University

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