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Microsystem Technologies
Published in: Microsystem Technologies 4-5/2014

01-04-2014 | Technical Paper

Unimorph and bimorph piezoelectric energy harvester stimulated by β-emitting radioisotopes: a modeling study

Authors: Ali B. Alamin Dow, Ulrich Schmid, Nazir P. Kherani

Published in: Microsystem Technologies | Issue 4-5/2014

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Abstract

We use energy methods and lumped-element modelling in the analysis and optimization of a miniaturized aluminum nitride based piezoelectric energy harvester which utilizes tritiated silicon as an uninterrupted energy source. Tritiated silicon serves as a radioisotope source which emits energetic β particles that results in an electrostatic force between the radioactive source and collector that traps the emitted particles. The generated electrostatic force will drive the charging and actuating cycles of the piezoelectric cantilever leading to a continuous charge–discharge cycles, thus inducing vibrations in the piezoelectric cantilever. The energy generated from the piezoelectric thin-film is appropriately rectified and stored to provide continuous and uninterrupted electrical power to a low-power devices. The modelled results have been benchmarked against available experimental data for a unimorph piezoelectric harvester with very good agreement. Furthermore, the model was applied to a bimorph piezoelectric harvester, showing that the output power can be doubled in relation to a unimorph design. Moreover, the model accounts for the entire range of design and operating factors such as the ambient medium and associated damping losses, current leakage, and device scaling.
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Literature
Anton SR, Sodano HA (2007) A review of power harvesting using piezoelectric materials (2003–2006). Smart Mater Struct 16(3):R1CrossRef
Beeby SP, Tudor MJ, White NM (2006) Energy harvesting vibration sources for microsystems applications. Meas Sci Technol 17(12):175–195 (S. R.)CrossRef
Blom F, Bouwstra S, Elwenspoek M, Fluitman J (1992) Dependence of the quality factor of micromachined silicon beam resonators on pressure and geometry. J Vac Sci Technol B Microelectron Process Phenom 10(1):19CrossRef
Cember H (1983) Introduction to health physics. Pergamon, New York
Cook-Chennault KA, Thambi N, Sastry AM (2008) Powering MEMS portable devices—a review of non-regenerative and regenerative power supply systems with special emphasis on piezoelectric energy harvesting systems. Smart Mater Struct 17(4):1–33. Art ID 043001. doi:10.​1088/​0964-1726/​17/​4/​043001
Corliss WR, Harvey DG (1964) Radioisotopic power generation. Prentice- Hall, Englewood Cliffs
Dareing DW, Thundat T, Jeon S, Nicholson M (2005) Modal analysis of microcantilever sensors with environmental damping. J Appl Phys 97(8):1–6CrossRef
Despesse G, Jager T, Chaillout J, Leger J, Vassilev A, Basrour S, Chalot B (2005) Fabrication and characterisation of high damping electrostatic micro devices for vibration energy scavenging. In: Proceedings of design, test, integration and packaging of MEMS and MOEMS, pp 386–390
Dubois-Ferriere H, Meier R, Fabre L, Metrailler P (2006) TinyNode: a comprehensive platform for wireless sensor network applications. In: The fifth international conference on information processing in sensor networks, pp 358–365
Duggirala R, Polcawich RG, Dubey M, Lal A (2008) Radioisotope thin-film fueled microfabricated reciprocating electromechanical power generator. J Microelectromech Syst 17(4):837–849CrossRef
Elfrink R, Kamel TM, Goedbloed M, Matova S, Hohlfeld D, Van Andel Y, Van Schaijk R (2009) Vibration energy harvesting with aluminum nitride-based piezoelectric devices. J Micromech Microeng 19(9):094005. doi:10.​1088/​0960-1317/​19/​9/​094005
Hosaka H, Itao K, Kuroda S (1994) Evaluation of energy dissipation mechanisms in vibrational microactuators. In: Proceedings of the IEEE workshop on micro electro mechanical systems, MEMS ‘94, pp 193–198
Jeon YB, Sood R, Jeong J, Kim S (2005) MEMS power generator with transverse mode thin film PZT. Sens Actuators A Phys 122(1):16–22 (SPEC. ISS)
Kherani NP, Kosteski T, Zukotynski S, Shmayda WT (1995) Tritiated amorphous silicon for micropower application. Fusion Technol 28:1609
Kosteski T, Kherani NP, Gaspari F, Zukotynski S, Shmayda WT (1998) Tritiated amorphous silicon films and devices. J Vac Sci Technol A Vac Surf Films 16(2):893–896CrossRef
Kulah H, Najafi K (2004) An electromagnetic micro power generator for low-frequency environmental vibrations. In: 17th IEEE international conference on micro electro mechanical systems (MEMS), pp 237–240
Li Y, Shawgo RS, Tyler B, Henderson PT, Vogel JS, Rosenberg A (2004) In vivo release from a drug delivery MEMS device. J Controlled Release 100(2):211–219CrossRef
Linden D, Reddy TB (2002) Handbook of batteries. McGraw-Hill, New York
Liu B, Chen KP, Kherani NP, Kosteski T, Costea S, Zukotynski S, Antoniazzi AB (2006) Tritiation of amorphous and crystalline silicon using T2 gas. Appl Phys Lett 89:044104CrossRef
Ma W, Wong M, Ruber L (2005) Dynamic simulation of an implemented electrostatic power micro-generator. In: Proceedings of design, test, integration and packaging of MEMS and MOEMS, pp 380–385
Miyazaki M, Tanaka H, Ono G, Nagano T, Ohkubo N, Kawahara T, Yano K (2003) Electric-energy generation using variable-capacitive resonator for power-free LSI: efficiency analysis and fundamental experiment. In: Proceedings of the international symposium onlow power electronics and design, ISLPED ‘03, pp 193–198 (25–27)
Renaud M, Karakaya K, Sterken T, Fiorini P, Van Hoof C, Puers R (2008) Fabrication, modelling and characterization of MEMS piezoelectric vibration harvesters. Sens Actuators A 145–146(1–2):380–386CrossRef
Roundy S, Wright PK, Rabaey J (2003) A study of low level vibrations as a power source for wireless sensor nodes. Comput Commun 26(11):1131–1144CrossRef
Sazonov E, Janoyan K, Jha R (2004) Wireless intelligent sensor network for autonomous structural health monitoring. In: Proceedings of SPIE—the international society for optical engineering, p 305
Senturia SD (2004) Microsystem design. Springer, New York
Sohn JW, Choi SB, Lee DY (2005) An investigation on piezoelectric energy harvesting for MEMS power sources. Proc Inst Mech Eng Part C J Mech Eng Sci 219(4):429–436CrossRef
Thomson WT (1988) Theory of vibration with applications, 3rd edn. Prentice-Hall, Englewood Cliffs
Tung S, Witherspoon SR, Roe LA, Silano A, Maynard DP, Ferraro N (2001) A MEMS- based flexible sensor and actuator system for space inflatable structures. Smart Mater Struct 10(6):1230–1239CrossRef
Warneke BA, Scott MD, Leibowitz BS, Zhou L, Bellew CL, Chediak JA, Kahn JM, Boser BE, Pister KSJ (2002) An autonomous 16 mm3 solar-powered node for distributed wireless sensor networks. Proc IEEE Sens 2:1510–1515CrossRef
Williams CB, Yates RB (1996) Analysis of a micro-electric generator for microsystems. Sens Actuators A 52(1–3):8–11CrossRef
Metadata
Title
Unimorph and bimorph piezoelectric energy harvester stimulated by β-emitting radioisotopes: a modeling study
Authors
Ali B. Alamin Dow
Ulrich Schmid
Nazir P. Kherani
Publication date
01-04-2014
Publisher
Springer Berlin Heidelberg
Published in
Microsystem Technologies / Issue 4-5/2014
Print ISSN: 0946-7076
Electronic ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-014-2093-z

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