Research and Applications: Emerging Technologies (e-ISSn:3048-4766)

Piezoelectric energy collecting frameworks are alluring for creating cutting edge self-fueled Microsystems. This paper depicts the essentials of piezoelectricity, working, wellsprings of energy accessible, benefits and detriments and furthermore moves capability for energy collecting inferred. The new headways in piezoelectric materials and resonator structures. Epitaxial development and grain finishing of piezoelectric materials is being created to accomplish a lot higher energy change proficiency is examined.

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Bertacchini, A., Scorcioni, S., Dondi, D., Larcher, L., Pavan, P., Todaro, M. T., ... & De Vittorio, M. (2011, September). AlN-based MEMS devices for vibrational energy harvesting applications. In 2011 Proceedings of the European Solid-State Device Research Conference (ESSDERC) (pp. 119-122). IEEE.

Apo, D. J., Sanghadasa, M., & Priya, S. (2014). Vibration modeling of arc-based cantilevers for energy harvesting applications. Energy Harvesting and Systems, 1(1-2), 57-68.

Apo, D. J., Sanghadasa, M., & Priya, S. (2013, April). Low frequency arc-based MEMS structures for vibration energy harvesting. In The 8th Annual IEEE International Conference on Nano/Micro Engineered and Molecular Systems (pp. 615-618). IEEE.

Cepnik, C., Lausecker, R., & Wallrabe, U. (2013). Review on electrodynamic energy harvesters—a classification approach. Micromachines, 4(2), 168-196.