The Woodruff School

SUMMARY

Locally resonant (LR) elastic/acoustic metamaterials enable bandgap formation at wavelengths much longer than the lattice parameter for low frequency vibration attenuation. Existing modeling and analysis approaches for LR metamaterials have been mostly focused on band structure dispersion analysis for waves propagating in an infinite metamaterial that comprises a perfectly periodic lattice arrangement. By neglecting the effects of boundary conditions, these models are only valid for high frequency applications, and cannot easily be extended to LR metamaterials operating at low frequencies. Thus, for real-world implementation of LR metamaterial concepts, the formation of LR bandgaps in infinite metamaterials must be reconciled with the interactions between the local resonators and the vibrational modes of finite structures. This work establishes a general modal analysis framework for analyzing both mechanical and electromechanical LR metastructures (i.e. LR metamaterial-based finite structures with specified boundary conditions), which explicitly obtains the LR bandgap in closed form under the assumption of an infinite number of resonators. Theoretical and experimental developments are presented for (1) general mechanical metastructures; (2) electromechanical metastructures based on piezoelectric bimorphs; (3) hybrid mechanical-electromechanical metastructures; (4) programmable electromechanical metastructures leveraging synthetic impedance shunt circuits; and (5) space- and time-modulated electromechanical metamaterials. It is shown that the bandgap size in the mechanical LR metastructures depends on the added mass due to the resonators, while the bandgap in electromechanical LR metastructures depends on the system-level electromechanical coupling. A root locus pole/zero placement method is developed to design shunt circuits for electromechanical metastructures to obtain any desired band structure, and experimental validations are presented for a programmable piezoelectric bimorph beam utilizing digital synthetic impedance circuits. Lastly, a fully coupled electromechanical framework is developed for piezoelectric metamaterials with spatiotemporal periodic shunt impedance, demonstrating the capability of these structures to break wave reciprocity.

SUBJECT:	Ph.D. Dissertation Defense

BY:	Christopher Sugino

TIME:	Wednesday, June 19, 2019, 1:00 p.m.

PLACE:	Love Building, 210

TITLE:	Dynamics of Mechanical and Electromechanical Locally Resonant Metastructures

COMMITTEE:	Dr. Alper Erturk, Chair (ME) Dr. Massimo Ruzzene (AE/ME) Dr. Levent Degertekin (ME/ECE) Dr. Aldo Ferri (ME) Dr. Laurence Jacobs (CE/ME) Dr. Yang Wang (CE)

SUMMARY Locally resonant (LR) elastic/acoustic metamaterials enable bandgap formation at wavelengths much longer than the lattice parameter for low frequency vibration attenuation. Existing modeling and analysis approaches for LR metamaterials have been mostly focused on band structure dispersion analysis for waves propagating in an infinite metamaterial that comprises a perfectly periodic lattice arrangement. By neglecting the effects of boundary conditions, these models are only valid for high frequency applications, and cannot easily be extended to LR metamaterials operating at low frequencies. Thus, for real-world implementation of LR metamaterial concepts, the formation of LR bandgaps in infinite metamaterials must be reconciled with the interactions between the local resonators and the vibrational modes of finite structures. This work establishes a general modal analysis framework for analyzing both mechanical and electromechanical LR metastructures (i.e. LR metamaterial-based finite structures with specified boundary conditions), which explicitly obtains the LR bandgap in closed form under the assumption of an infinite number of resonators. Theoretical and experimental developments are presented for (1) general mechanical metastructures; (2) electromechanical metastructures based on piezoelectric bimorphs; (3) hybrid mechanical-electromechanical metastructures; (4) programmable electromechanical metastructures leveraging synthetic impedance shunt circuits; and (5) space- and time-modulated electromechanical metamaterials. It is shown that the bandgap size in the mechanical LR metastructures depends on the added mass due to the resonators, while the bandgap in electromechanical LR metastructures depends on the system-level electromechanical coupling. A root locus pole/zero placement method is developed to design shunt circuits for electromechanical metastructures to obtain any desired band structure, and experimental validations are presented for a programmable piezoelectric bimorph beam utilizing digital synthetic impedance circuits. Lastly, a fully coupled electromechanical framework is developed for piezoelectric metamaterials with spatiotemporal periodic shunt impedance, demonstrating the capability of these structures to break wave reciprocity.