The present work reports the effect of lamination of biocompatible lithium sodium potassium niobate [Li-0.06(Na0.5K0.5)(0.94)NbO3, LNKN] multilayered tapes between hydroxyapatite (HA) layers on the dielectric and electrical properties of HA. The LNKN tapes were laminated between HA layers via various buffer interlayers. It has been found that for the optimal molar ratio X = 3-7 of LNKN in the LNKN : HA (X : 1) buffer interlayer, good adhesion between HA and LNKN layers were observed. The effect of lamination of buffer and HA layers and subsequent sintering on the dielectric and electrical properties of inserted ferroelectric LNKN has been evaluated after removing these laminated layers from the composite (HB-LNKN). The crystal structure of HB-LNKN has been changed from the tetragonal to the orthorhombic phase. In addition, the dielectric measurement suggests that the tetragonal region, i.e., the range between TO-T and TC for HB-LNKN has also been reduced as compared to that of as-sintered LNKN. The variation in the tetragonal region in HB-LNKN has been found to depend on the composition ( X) of the buffer layer in the parent laminated composite. For the buffer layer composition X = 7, the improved piezoelectric (d(33) - 104 pC N-1) as well as ferroelectric (E-c - 11 kV cm(-1), P-max - 23 mu C cm(-2)) response of HB-LNKN was observed. The associated polarization mechanisms in the context of ferroelectric LNKN have also been explored. An approximate 6-times increase in the polarizability of HA (for X = 7) is obtained without affecting its biocompatibility by the proposed concept of the laminated composite. In addition, the developed laminated composite is piezoelectric (d(33) = 2 pC N-1) in nature, like living bone. Further, the effect of increased polarizability of hydroxyapatite (for X = 7) on the in vitro bioactivity has been examined after immersion in simulated body fluid (SBF) for 3, 7 and 14 days, respectively. The augmented polarizability of HA almost doubled the apatite formation rate in SBF.
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