We present a deep investigation of pyroelectric fields generated by lithium niobate crystals through integrated microheater structures. The microheaters are made of highly compact titanium microcircuits able to dissipate heat through a low-power consuming Joule effect. Microheaters with diverse geometries were designed and fabricated on the +Z face of lithium niobate crystals, in order to characterize pyroelectric fields with different distributions. The pyroelectric effect was studied under ambient conditions analysing the current impulses detected using a metallic probe connected to an oscilloscope. The current impulses were related to the air breakdown induced by the electric field arising between the −Z face of the crystal and the metallic tip. We show that the fabrication technique is relatively easy to accomplish and we analyse the thermal behaviour of the microheaters both theoretically and experimentally. The results show how such microheaters are able to control the intensity and the spatial distribution of the pyroelectric fields at microscale.
Investigation of pyroelectric fields generated by lithium niobate crystals through integrated microheaters / Bhowmick, Shomnath; Iodice, M.; Gioffrã, M.; Breglio, Giovanni; Irace, Andrea; Riccio, Michele; Romano, Gianpaolo; Grilli, S.; Ferraro, P.; Mecozzi, Laura; Coppola, S.; Gennari, O.; Rega, R.; Coppola, G.. - In: SENSORS AND ACTUATORS. A, PHYSICAL. - ISSN 0924-4247. - 261:(2017), pp. 140-150. [10.1016/j.sna.2017.05.010]
Investigation of pyroelectric fields generated by lithium niobate crystals through integrated microheaters
BREGLIO, GIOVANNI;IRACE, ANDREA;RICCIO, MICHELE;ROMANO, GIANPAOLO;MECOZZI, LAURA;
2017
Abstract
We present a deep investigation of pyroelectric fields generated by lithium niobate crystals through integrated microheater structures. The microheaters are made of highly compact titanium microcircuits able to dissipate heat through a low-power consuming Joule effect. Microheaters with diverse geometries were designed and fabricated on the +Z face of lithium niobate crystals, in order to characterize pyroelectric fields with different distributions. The pyroelectric effect was studied under ambient conditions analysing the current impulses detected using a metallic probe connected to an oscilloscope. The current impulses were related to the air breakdown induced by the electric field arising between the −Z face of the crystal and the metallic tip. We show that the fabrication technique is relatively easy to accomplish and we analyse the thermal behaviour of the microheaters both theoretically and experimentally. The results show how such microheaters are able to control the intensity and the spatial distribution of the pyroelectric fields at microscale.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.