Abstract
Ferroelectric lithium niobate (LiNbO3) crystals with an engineered domain structure have a number of applications in optical systems for generation of multiple laser radiation harmonics, acoustooptics, precision actuators, vibration and magnetic field sensors, including those for high-temperature applications, and prospectively, in non-volatile computer memory. We have studied the effect of charged domain boundary on the formation of induced domain structures in congruent lithium niobate (LiNbO3) crystals at the non-polar x-cut. Bi- and polydomain ferroelectric structures containing charged “head-to-head” and “tail-to-tail” type domain boundaries have been formed in the specimens using diffusion annealing in air ambient close to the Curie temperature and infrared annealing in an oxygen free environment. The surface potential near the charged domain wall has been studied using an atomic force microscope (AFM) in Kelvin mode. We have studied surface wedge-shaped induced microscopic domains formed at the charged domain boundary and far from that boundary by applying electric potential to the AFM cantilever which was in contact with the crystal surface. We have demonstrated that the morphology of the induced domain structure depends on the electrical conductivity of the crystals. The charged “head-to-head” domain boundary has a screening effect on the shape and size of the domain induced at the domain wall. Single wedge-shaped domains forming during local repolarization of reduced lithium niobate crystals at the AFM cantilever split into families of microscopic domains in the form of codirectional beams emerging from a common formation site. The charged domain wall affects the topography of the specimens by inducing the formation of an elongated trench, coincident with the charged boundary, during reduction annealing.
Highlights
Ferroelectric lithium niobate (LiNbO3) crystals with an engineered domain structure have a number of applications in optical systems for generation of multiple laser radiation harmonics, acoustooptics, precision actuators, vibration and magnetic field sensors, including those for high-temperature applications, and prospectively, in non-volatile com
Many authors observed earlier [32, 42, 43] that the shape, length and configuration of the forming domains may vary depending on the method of local repolarization in LiNbO3 crystals with the scanning probe microscope (SPM) cantilever
If the probe remained in contact with the specimen surface while moving between the polarization points the spontaneous polarization vectors of the forming domains were directed against the cantilever electric field [32], and additional micro- and nanodomains formed along the cantilever route [42, 43]
Summary
Ferroelectric lithium niobate (LiNbO3) crystals with an engineered domain structure have a number of applications in optical systems for generation of multiple laser radiation harmonics, acoustooptics, precision actuators, vibration and magnetic field sensors, including those for high-temperature applications, and prospectively, in non-volatile com-Kislyuk AM et al.: Tailoring of stable induced domains puter memory [1,2,3,4,5,6,7,8,9,10,11,12]. “head-to-head” and “tail-to-tail” domain boundaries are arranged at a nearly 90° angle to the spontaneous polarization vectors of the adjacent domains and have their own bound charge (positive for head-to-head boundaries and negative for tail-to-tail ones). This charge increases the free energy of the crystal and is compensated by mobile carriers causing local changes in the electrophysical properties near the domain boundaries
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