Field-induced transformation of ferroelectric domain states in KTN crystal

Quanxin Yang; Xiaojin Li; Hongliang Liu; Yingying Ren; Pengfei Wu

doi:10.3788/COL202119.111602

[1] X.-P. Wang, Q.-G. Li, Y.-G. Yang, Y.-Y. Zhang, X.-S. Lv, L. Wei, B. Liu, J.-H. Xu, L. Ma, J.-Y. Wang. Optical, dielectric and ferroelectric properties of KTa0.63Nb0.37O3 and Cu doped KTa0.63Nb0.37O3 single crystals. J. Mater. Sci. Mater. Electron., 27, 13075(2016).

[2] F. Huang, C. Hu, Z. Zhou, X. Meng, P. Tan, Y. Wang, C. Wang, H. Tian. Improving strain in single crystal by composition-gradients design. Acta Mater., 200, 24(2020).

[3] X. Li, Q. Yang, H. Liu, Y. Ren, X. Wang, P. Wu. UV-enhanced conductive and dielectric properties in KTN crystal. Ceram. Int., 47, 11989(2021).

[4] X. Li, Q. Yang, X. Zhang, S. He, X. Wang, H. Liu, P. Wu. High transparency induced by electric fields using KTN crystals. J. Alloys Compd., 842, 155702(2020).

[5] X. Zheng, H. Zhao, X. Wang, B. Liu, J. Yu, X. Zhao. Phase evolution and dielectric/ferroelectric properties of KTa0.67Nb0.33O3 single crystal. Ceram. Int., 41, S197(2015).

[6] Y. C. Chang, C. Wang, S. Yin, R. C. Hoffman, A. G. Mott. Giant electro-optic effect in nanodisordered KTN crystals. Opt. Lett., 38, 4574(2013).

[7] Q. Lu, B. Li, Z. Li, B. Ge. Field-induced lifetime enhancement of photorefractive gratings in a Mn:Fe:KTN crystal. Opt. Lett., 42, 2407(2017).

[8] X. Zhang, Q. Yang, H. Liu, X. Wang, S. He, X. Li, P. Wu. Switching effects of spontaneously formed superlattices in relaxor ferroelectrics. Opt. Mater. Express, 9, 4081(2019).

[9] Q. Yang, X. Zhang, H. Liu, X. Wang, Y. Ren, S. He, X. Li, P. Wu. Dynamic relaxation process of a 3D super crystal structure in a Cu:KTN crystal. Chin. Opt. Lett., 18, 021901(2020).

[10] F. Di Mei, L. Falsi, M. Flammini, D. Pierangeli, P. Di Porto, A. J. Agranat, E. DelRe. Giant broadband refraction in the visible in a ferroelectric perovskite. Nat. Photon., 12, 734(2018).

[11] Y. Wang, X. Meng, H. Tian, C. Hu, P. Xu, P. Tan, Z. Zhou. Dynamic evolution of polar regions in KTa0.56Nb0.44O3 near the para-ferroelectric phase transition. Cryst. Growth Des., 19, 1041(2019).

[12] X. Li, Q. Yang, X. Zhang, S. He, H. Liu, P. Wu. Heating-rate-dependent dielectric properties of KTa0.58Nb0.42O3 crystal in paraelectric phase. Cryst. Growth Des., 20, 2578(2020).

[13] P. Wu, X. Jiang, B. Zhang, S. He, Q. Yang, X. Li, Y. Ren, F. Chen, H. Liu. Mode-controllable waveguide fabricated by laser-induced phase transition in KTN. Opt. Express, 28, 25633(2020).

[14] X. Li, Q. Yang, X. Zhang, S. He, H. Liu, P. Wu. Low DC electric-field-induced phase transition in KTa0.59Nb0.41O3 crystal. Cryst. Growth Des., 20, 1248(2019).

[15] S. He, Z. Zhang, H. Liu, S. Akhmadaliev, S. Zhou, X. Wang, P. Wu. Spatial solitons in KTaxNb1-xO3 waveguides produced by swift carbon ion irradiation and femtosecond laser ablation. Appl. Phys. Express, 12, 076502(2019).

[16] S. He, Q. Yang, B. Zhang, Y. Ren, H. Liu, P. Wu, Y. Yao, F. Chen. A waveguide mode modulator based on femtosecond laser direct writing in KTN crystals. Results Phys., 18, 103307(2020).

[17] S. He, Q. Yang, X. Li, H. Liu, L. Cao, S. Akhmadaliev, X. Wang, Y. Ren, S. Zhou, P. Wu. Para-ferroelectric phase transition driven by swift heavy-ion irradiation in KTN crystal. Appl. Surf. Sci., 519, 146261(2020).

[18] V. Laur, A. Moussavou, G. Tanne, P. Laurent, V. Bouquet, S. Deputier, M. Guilloux-Viry, F. Huret. Reconfigurable circuits for wireless applications using KTN ferroelectrics. 2007 European Microwave Conference, 102(2007).

[19] X. Meng, H. Tian, C. Hu, J. Yang, L. Li, B. Yang, Z. Zhou. Elastic, piezoelectric, and dielectric properties of high-quality KTa0.53Nb0.47O3 single crystal with tetragonal phase. J. Alloys Compd., 773, 21(2019).

[20] W. Haas, R. Johannes. Linear electrooptic effect in potassium tantalate niobate crystals. Appl. Opt., 6, 2007(1967).

[21] S. Loheide, H. Hesse, E. Krätzig, K. H. Ringhofer. Photorefractive properties of tetragonal potassium tantalate-niobate crystals. Opt. Mater., 2, 65(1993).

[22] S. Riehemann, D. Sabbert, S. Loheide, F. Matthes, G. von Bally, E. Krätzig. Holographic double-exposure interferometry with tetragonal KTa1−xNbxO3:Fe crystals. Opt. Mater., 4, 437(1995).

[23] F. Huang, C. Hu, Z. Xian, X. Sun, Z. Zhou, X. Meng, P. Tan, Y. Zhang, X. Huang, Y. Wang, H. Tian. Photovoltaic properties in an orthorhombic Fe doped KTN single crystal. Opt. Express, 28, 34754(2020).

[24] X. Cao, H. Tian, C. Hu, Y. Wang, X. Li, L. Li, X. Sun, Z. Zhou. Discovery and evolution of double P-E loops in a tetragonal Fe-doped KTa0.57Nb0.43O3 single crystal. J. Am. Ceram. Soc., 101, 3755(2018).

[25] P. Zhang, D. Liu, A. Yang, J. Zhu. Optimization of compensation for high spatial frequency in distorted wavefront using optical phase conjugation. Chin. Opt. Lett., 17, 070901(2019).

[26] Y. Niu, L. Yang, D. Guo, Y. Chen, X. Li, G. Zhao, X. Hu. Efficient 671 nm red light generation in annealed proton-exchanged periodically poled LiNbO3 waveguides. Chin. Opt. Lett., 18, 111902(2020).

[27] C. Qiu, B. Wang, N. Zhang, S. Zhang, J. Liu, D. Walker, Y. Wang, H. Tian, T. R. Shrout, Z. Xu, L. Q. Chen, F. Li. Transparent ferroelectric crystals with ultrahigh piezoelectricity. Nature, 577, 350(2020).

[28] X. Wang, J. Wang, Y. Yu, H. Zhang, R. I. Boughton. Growth of cubic KTa1−xNbxO3 crystal by Czochralski method. J. Cryst. Growth, 293, 398(2006).

[29] H.-L. Hu, L.-Q. Chen. Three-dimensional computer simulation of ferroelectric domain formation. J. Am. Ceram. Soc., 81, 492(1998).

[30] Y. Ishibashi, E. Salje. A theory of ferroelectric 90 degree domain wall. J. Phys. Soc. Jpn., 71, 2800(2002).

Data from CrossRef