A series of heteroepitaxial BaxSr1−xTiO3 thin films with composition x=0.50 were deposited on (001) MgO substrates by pulsed-laser deposition. The thickness of the films was varied from 14 to 500 nm to produce a systematically decreasing level of in-plane tensile stresses. The microstructural and crystallographic features of the films were determined via transmission electron microscopy and x-ray diffraction. A theoretical treatment of the in-plane misfit strain as a function of film thickness is in agreement with the measured out-of-plane lattice parameters. Electrical measurements indicate a drop in the dielectric constant from 2350 for highly stressed thin films to 1700 for relaxed thicker films. The variation in the dielectric constant with the misfit strain is in accordance with a thermodynamic model developed. The relationship between the dielectric constant and electric field is also described by extending the thermodynamic model and taking the effect of electric field into account. A new definition of tunability is adopted to study the effect of strain on tunability.

Topics
Electric measurements, Crystal lattices, Dielectric properties, Epitaxy, Pulsed laser deposition, Thin films, Transmission electron microscopy, X-ray diffraction, Tensile stress
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β=α2+4A. The value of α2 is not available for BST, neither is it for SrTiO3, so we used value for BaTiO32=−5.5×108J m5 C−4) to do an estimation. The values of A is 0.97×109J m5 C−4 approximately (Ref. 6), therefore β is 3.35×109J m5 C−4.
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© 2001 American Institute of Physics.
2001
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