Technology for the creation of ferroelectric regular domain structures using interfering elastic waves

V. Krutov, A. S. Sigov
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Abstract

Objectives. In many laboratories around the world, work is underway in the field of domain engineering of ferroelectrics. For a number of years, RTU MIREA has been conducting research on the creation of a high-performance technology for the formation of ferroelectric photonic and phononic crystals. The technology is characterized by a short duration of the technological cycle and provides the necessary depth of spatially periodic domain inversion. The key element of the technology is the combined effect of a uniform electric field and interfering high-frequency elastic waves that create a temperature grating. The technology is universal in relation to ferroelectrics of varying degrees of acoustic transparency, which is achieved by using highly dissipative liquid electrodes of a certain thickness. In this case, the energy of elastic waves practically does not penetrate into the ferroelectric, so the manifestation of undesirable effects is excluded. The purpose of this review article is to analyze the results of work carried out at RTU MIREA in the field of technology for the formation of ferroelectric regular domain structures (RDSs) during the period from 2008 to the present.Methods. Provisions of the theory of propagation, refraction and interference of elastic waves in condensed media are used, in particular, the Newtonian model of a liquid as applied to shear waves, as well as computer simulation. When considering the main stages of the Double Pulse heterothermal technology for the formation of RDSs, methods of analysis and synthesis were applied.Results. The possibility of forming not only micro-, but also submicron RDSs is shown. Recommendations are given on the choice of the type and specific properties of liquid electrodes, the angles between the direction of propagation of interfering waves, and their frequency. It is shown, in particular, that the use of highly dissipative ionic liquids as liquid electrodes creates favorable conditions for the formation of an RDS with a short period at room temperature. Thus, on shear waves with electrodes based on LiPF6-PC at a frequency of 300 MHz, RDS with a period of about 2 цт can be created. The main technological parameters are determined both for the case of the action of longitudinal elastic waves and for the case of shear waves with horizontal polarization. The results are applicable to ferroelectrics such as lithium niobate, potassium titanyl phosphate, and lead zirconate titanate.Conclusions. The proposed and studied methods are focused on the mass production of devices based on RDSs, in particular, on the manufacturing of optical parametric oscillators, acoustoelectronic devices, as well as terahertz wave generators and second harmonic oscillators. The technology has a short duration of the technological cycle, comparable to the polarization switching time in the used ferroelectric.
利用干涉弹性波制造铁电规则畴结构的技术
目标。在世界各地的许多实验室中,铁电体的领域工程正在进行中。多年来,RTU MIREA一直在研究创造一种高性能的铁电光子和声子晶体的形成技术。该技术的特点是技术周期短,提供了必要的空间周期域反演深度。该技术的关键要素是均匀电场和干扰高频弹性波的联合作用,从而产生温度光栅。该技术在不同程度的声透明铁电体中是通用的,这是通过使用一定厚度的高耗散液体电极来实现的。在这种情况下,弹性波的能量实际上不会渗透到铁电体中,因此排除了不良效应的表现。本文旨在分析RTU MIREA自2008年至今在铁电规则畴结构(rds)形成技术领域所开展的工作成果。使用了弹性波在凝聚介质中的传播、折射和干涉理论的规定,特别是应用于剪切波的牛顿液体模型,以及计算机模拟。针对双脉冲异热法制备rds的主要阶段,采用了分析和合成的方法。指出了形成微、亚微米rds的可能性。对液体电极的类型和特性的选择、干涉波的传播方向和频率之间的夹角提出了建议。特别是,使用高耗散离子液体作为液体电极,为室温下短周期RDS的形成创造了有利条件。因此,在频率为300 MHz的LiPF6-PC电极剪切波上,可以产生周期约为2 цт的RDS。确定了纵弹性波作用下和横波水平极化作用下的主要工艺参数。结果适用于铌酸锂、磷酸钛酸钾、钛酸锆铅等铁电体。提出和研究的方法集中在基于rds的器件的批量生产,特别是光学参量振荡器,声电子器件,以及太赫兹波发生器和二次谐波振荡器的制造。该技术的技术周期短,可与旧铁电中的极化开关时间相媲美。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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