High-temperature electrical conductivity in piezoelectric lithium niobate

Lithium niobate is a promising candidate for use in high-temperature piezoelectric devices due to its high Curie temperature ([Formula: see text]1483 K) and strong piezoelectric properties. However, the piezoelectric behavior has, in practice, been found to degrade at various temperatures as low as 573 K, with no satisfactory explanation available in the literature. We, therefore, studied the electrical conductivity of congruent lithium niobate single crystals in the temperature range of 293–1273 K with an 500 mV excitation at frequencies between 20 Hz and 20 MHz. An analytical model that generalizes the universal dielectric relaxation law with the Arrhenius equation was found to describe the experimental temperature and frequency dependence and helped discriminate between conduction mechanisms. Electronic conduction was found to dominate at low temperatures, leading to low overall electrical conductivity. However, at high temperatures, the overall electrical conductivity increases significantly due to ionic conduction, primarily with lithium ions (Li+) as charge carriers. This increase in electrical conductivity can, therefore, cause an internal short in the lithium niobate crystal, thereby reducing observable piezoelectricity. Interestingly, the temperature above which ionic conductivity dominates depends greatly on the excitation frequency: at a sufficiently high frequency, lithium niobate does not exhibit appreciable ionic conductivity at high temperature, helping explain the conflicting observations reported in the literature. These findings enable an appropriate implementation of lithium niobate to realize previously elusive high-temperature piezoelectric applications.

[1]  R. Zednik,et al.  High temperature characterization of piezoelectric lithium niobate using electrochemical impedance spectroscopy resonance method , 2017 .

[2]  A. El Bachiri,et al.  Dielectric and electrical properties of LiNbO3 ceramics , 2016 .

[3]  Qinglin Wang,et al.  Mixed conduction and grain boundary effect in lithium niobate under high pressure , 2015 .

[4]  Soma Dutta,et al.  High-Temperature Piezoelectrics with Large Piezoelectric Coefficients , 2015, Journal of Electronic Materials.

[5]  P. Fielitz,et al.  Tantalum and niobium diffusion in single crystalline lithium niobate , 2014 .

[6]  F. Bennani,et al.  Ionic and Polaronic Conductivity of Lithium Niobate , 2014 .

[7]  A. Weidenfelder,et al.  Electrical and electromechanical properties of stoichiometric lithium niobate at high-temperatures , 2012 .

[8]  P. Heitjans,et al.  Low-Temperature DC Conductivity of LiNbO3 Single Crystals , 2012 .

[9]  A. Weidenfelder,et al.  Transport and Electromechanical Properties of Stoichiometric Lithium Niobate at High Temperatures , 2012 .

[10]  P. Heitjans,et al.  Li self-diffusion in lithium niobate single crystals at low temperatures. , 2012, Physical chemistry chemical physics : PCCP.

[11]  A. Weidenfelder,et al.  Oxygen-18 tracer diffusion in nearly stoichiometric single crystalline lithium niobate , 2011 .

[12]  Jianmin Shi,et al.  Defect chemistry, redox kinetics, and chemical diffusion of lithium deficient lithium niobate. , 2011, Physical chemistry chemical physics : PCCP.

[13]  Bernhard R. Tittmann,et al.  High temperature ultrasonic transducer up to 1000 °C using lithium niobate single crystal , 2010 .

[14]  C Merschjann,et al.  Electron small polarons and bipolarons in LiNbO3 , 2009, Journal of physics. Condensed matter : an Institute of Physics journal.

[15]  F. S. Welsh,et al.  Temperature Dependence of the Elastic, Piezoelectric, and Dielectric Constants of Lithium Tantalate and Lithium Niobate , 1971 .

[16]  G. E. Peterson,et al.  Nonstoichiometry and Crystal Growth of Lithium Niobate , 1971 .

[17]  A. Weidenfelder,et al.  Electronic and Ionic Transport Mechanisms of Stoichiometric Lithium Niobate at High-Temperatures , 2013 .

[18]  A. Jonscher Dielectric relaxation in solids , 1983 .