High power density in a piezoelectric energy harvesting ceramic by optimizing the sintering temperature of nanocrystalline powders

Abstract

Piezoelectric energy harvesting is the research hotspot in the field of new energy, and its core is to prepare piezoelectric ceramics with high transduction coefficient (d33×g33) and large mechanical quality factor (Qm) as well. In addition, the miniaturization of the piezoelectric energy harvester also requires the material to have a submicron fine grain structure. In this work, submicron-structured ternary system, MnO2-doped Pb(Zn1/3Nb2/3)O3-Pb(Zr0.5Ti0.5)O3 was constructed by pressureless sintering of nanocrystalline powders, which has been synthesized for the first time by high-energy ball milling route thereby evading the calcination stage. The microstructure and the energy harvesting characteristics were tailored through changing the sintering temperature. It was found that 1000°C sintered fine-grained specimen (mean grain size ∼0.95μm) showed the maximum d33×g33 value of 9627×10−15m2/N, meanwhile Qm was as large as 774, which was almost seven times larger than pure counterpart. In the mode of the cantilever-type energy harvester, a high power density of 1.5μW/mm3 were obtained for 1000°C sintered specimen at a low resonance frequency of 90Hz and acceleration of 10m/s2, which were further increased to 29.2μW/mm3 when the acceleration increased to 50m/s2, showing the potential applications as a next generation high power multilayer energy harvester.