Three-dimensional quasi-periodic ferroelectric domain structure and its second harmonic generation effect in potassium tantalate niobate crystal

Zijian Zhang; Xing Wen; Yuan Zhou; Yu Wang; Xiangda Meng; Zhenghao Li; Chengpeng Hu; Peng Tan; Qinghai Song; Hao Tian

doi:10.20517/microstructures.2025.36

Microstructures ›› 2026, Vol. 6 ›› Issue (2) -2026028. DOI: 10.20517/microstructures.2025.36

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Three-dimensional quasi-periodic ferroelectric domain structure and its second harmonic generation effect in potassium tantalate niobate crystal

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Abstract

Nonlinear photonic crystals (NPCs) have garnered significant attention due to their capability to manipulate and enhance optical interactions via quasi-phase-matching. The periodic domain inversion structures inside NPCs, corresponding to periodically modulated second-order nonlinear coefficients χ⁽²⁾, enable the generation of light at new frequencies. However, due to the internal stress and defects, forming a structurally perfect superlattice in naturally grown crystals is challenging, and artificial engineering often entails high costs and complex procedures. In this study, we successfully fabricated a unique three-dimensional (3D) potassium tantalate niobate (KTN) NPC using a direct current poling treatment. Nonlinear Cherenkov diffraction occurs when the fundamental light propagates parallel to the poling direction, whereas nonlinear Bragg diffraction is observed when the light is incident perpendicular to the poling direction. By analyzing both the linear and nonlinear optical responses of the stably poled KTN crystal, we reveal the 3D distribution of ferroelectric domains, which advances the understanding of ferroelectric domain dynamics during the poling process and opens new avenues for research in anisotropic nonlinear optics and optoelectronic applications.

Keywords

Nonlinear photonic crystals / ferroelectric domains / quasi-phase-matching / nonlinear optical properties

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Zijian Zhang, Xing Wen, Yuan Zhou, Yu Wang, Xiangda Meng, Zhenghao Li, Chengpeng Hu, Peng Tan, Qinghai Song, Hao Tian. Three-dimensional quasi-periodic ferroelectric domain structure and its second harmonic generation effect in potassium tantalate niobate crystal. Microstructures, 2026, 6(2): -2026028 DOI:10.20517/microstructures.2025.36

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Chakkoria JJ,Mitchell A.Ferroelectric domain engineering of Lithium niobate.OEA2025;8:240139

[2]	Gómez-Tornero A,Molina P,Bausá LE.Enhancing nonlinear interactions by the superposition of plasmonic lattices on χ⁽²⁾ -nonlinear photonic crystals.ACS Photonics2021;8:2529-37

[3]	Zhang B,Chen F.Recent advances in femtosecond laser direct writing of three-dimensional periodic photonic structures in transparent materials.Adv Photon2025;7

[4]	Aashna P,Cao Y.Periodic domain inversion in single crystal barium titanate-on-insulator thin film.Adv Sci2024;11:e2406248 PMCID:PMC11558107

[5]	Li J,Kougo J.Development of ferroelectric nematic fluids with giant-ε dielectricity and nonlinear optical properties.Sci Adv2021;7:eabf5047 PMCID:PMC8059932

[6]	Liu S,Mazur LM.Highly efficient 3D nonlinear photonic crystals in ferroelectrics.Adv Opt Mater2023;11:2300021

[7]	Lai P,Liu X.Multiplexing linear and nonlinear bragg diffractions through volume gratings fabricated by femtosecond laser writing in lithium niobate crystal.Photonics2023;10:562

[8]	Vogler-Neuling VV,Morandi A,Dénervaud E.Photonic assemblies of randomly oriented nanocrystals for engineered nonlinear and electro-optic effects.ACS Photonics2022;9:2193-203 PMCID:PMC9307051

[9]	Wang R,Wang X.Hollow cylindrical three-dimensional nonlinear photonic crystal for annular beam generation.Appl Phys Lett2024;125:121113

[10]	Yu C,Xu T,Sheng Y.Helically twisted nonlinear photonic crystals.Opt Lett2024;49:4745-8

[11]	Su Y,Chen H.High-efficiency nonlinear frequency conversion enabled by optimizing the ferroelectric domain structure in x-cut LNOI ridge waveguide.Nanophotonics2024;13:3477-84 PMCID:PMC11501146

[12]	Mishra J,Ng E.Mid-infrared nonlinear optics in thin-film lithium niobate on sapphire.Optica2021;8:921

[13]	Wu H,Hu B.Widely tunable continuous-wave visible and mid-infrared light generation based on a dual-wavelength switchable and tunable random Raman fiber laser.Photon Res2023;11:808

[14]	Xu T,Chen X.Three-dimensional nonlinear photonic crystal in ferroelectric barium calcium titanate.Nat Photon2018;12:591-5

[15]	Li C,Wu Y.Three-dimensional nonlinear photonic crystal in naturally grown potassium-tantalate-niobate perovskite ferroelectrics.Light Sci Appl2020;9:193 PMCID:PMC7687908

[16]	Reitzig S,Ratzenberger J.High-speed hyperspectral imaging of ferroelectric domain walls using broadband coherent anti-Stokes Raman scattering.Appl Phy Lett2022;120:162901

[17]	Sebastián-Vicente C,Laubrock S,García-Cabañes A.All-optical domain inversion in LiNbO₃ crystals by visible continuous-wave laser irradiation.ACS Photonics2024;11:2624-36 PMCID:PMC11258989

[18]	Pan JT,Ma LL.Nonlinear geometric phase coded ferroelectric nematic fluids for nonlinear soft-matter photonics.Nat Commun2024;15:8732 PMCID:PMC11464912

[19]	Wang R,Wang X,Li F.Second-harmonic flat-top beam shaping via a three-dimensional nonlinear photonic crystal.Opt Lett2024;49:1097-100

[20]	Chen P,Wei D.Quasi-phase-matching-division multiplexing holography in a three-dimensional nonlinear photonic crystal.Light Sci Appl2021;10:146 PMCID:PMC8282809

[21]	Tan P,Huang F.Strain-gradient-controlled disorder dynamics in chemically substituted ferroelectrics.Phys Rev Appl2019;11:024037

[22]	Wei D,Wang H.Experimental demonstration of a three-dimensional lithium niobate nonlinear photonic crystal.Nat Photon2018;12:596-600

[23]	Di Mei F,Flammini M.Giant broadband refraction in the visible in a ferroelectric perovskite.Nat Photon2018;12:734-8

[24]	Wu Y,Tian G.Periodically poled nonlinear photonic crystal KTa_0.51Nb_0.49O₃ Combining wide transparent range and large quadratic coefficient.Adv Opt Mater2022;10:2201010

[25]	Gelkop Y,Frishman S.Hyperbolic optics and superlensing in room-temperature KTN from self-induced k-space topological transitions.Nat Commun2021;12:7241 PMCID:PMC8668897

[26]	Falsi L,Gelkop Y.Anomalous optical properties of KTN:Li ferroelectric supercrystals.Nanomaterials2023;13:899 PMCID:PMC10005727

[27]	Gao X,Chen Z.The mechanism for the enhanced piezoelectricity in multi-elements doped (K,Na)NbO₃ ceramics.Nat Commun2021;12:881 PMCID:PMC7873261

[28]	Ren CP,Hong XH.Conical quasi-phase-matching second harmonic generation in a 2D photonic crystal with hybrid Ewald geometric method.Opt Express2024;32:16523-32

[29]	Wu Y,Wang Z.Finding a novel borate ferroelectric with random domain structures for deep-UV quasi-phase-matching.Adv Mater2025;e2505930

[30]	Rytz D,Höchli UT.Elastic properties in quantum ferroelectric KTa_1-xNb_xO₃.Phys Rev B1983;27:6830-40

[31]	Wang X,Chen P.Potassium tantalate niobate crystals: efficient quadratic electro-optic materials and their laser modulation technology.J Mater2023;9:838-54

[32]	Zhang Y,Liu F.Growth and characterization of large size lead-free ferroelectric K(Ta,Nb)O₃ single crystal.J Am Ceram Soc2021;104:5182-91

[33]	Falsi L,Di Mei F.Constraint-free wavelength conversion supported by giant optical refraction in a 3D perovskite supercrystal.Commun Mater2020;1:77

[34]	Wen X,Wang Y.Broadband nonlinear Bragg diffraction from self-assembled structures in potassium tantalate niobate crystals.Appl Phys Lett2024;125:191103

[35]	Xu T,Yu H,Zhang Y.A naturally grown three-dimensional nonlinear photonic crystal.Appl Phys Lett2016;108:051907

[36]	Ayoub M,Denz C.Second harmonic generation in multi-domain χ² media: from disorder to order.Opt Express2011;19:11340-54

[37]	Zhang Y,Guo Q.Characterization of domain distributions by second harmonic generation in ferroelectrics.NPJ Comput Mater2018;4:95

[38]	Mishina ED,Barskiy DR.Domain orientation in ultrathin (Ba,Sr)TiO₃ films measured by optical second harmonic generation.J Appl Phys2003;93:6216-22

[39]	Pierangeli D,Di Mei F.Super-crystals in composite ferroelectrics.Nat Commun2016;7:10674 PMCID:PMC4770076

[40]	Xin F,Gelkop Y.Evidence of 3D topological-domain dynamics in KTN:Li polarization-supercrystal formation.Phys Rev Lett2024;132:066603

[41]	Wang J,Tang S.General principle of ferroelectric topological domain formation.Sci Adv2025;11:eadu6223

[42]	Loheide S,Mersch F,Krätzig E.Refractive indices, permittivities, and linear electrooptic coefficients of tetragonal potassium tantalate-niobate crystals.Phys Stat Sol (a)1993;137:257-65

[43]	Shapira A.Phase-matched nonlinear diffraction.Opt Lett2011;36:1933-5

[44]	Tunyagi AR,Betzler K.Noncollinear optical frequency doubling in strontium barium niobate.Phys Rev Lett2003;90:243901

[45]	Ayoub M,Denz C.Ferroelectric domain diagnostics near the phase transition by Čerenkov second-harmonic generation.Opt Mater Express2017;7:3448

[46]	Hum DS.Quasi-phasematching.Comptes Rendus2007;8:180-98

[47]	Lo Presti L,Soave R.Observation of an exotic lattice structure in the transparent KTa_1-xNb_xO₃ perovskite supercrystal.Phys Rev B2020;102:214110

[48]	Biancoli A,Jones JL.Breaking of macroscopic centric symmetry in paraelectric phases of ferroelectric materials and implications for flexoelectricity.Nat Mater2015;14:224-9