Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-08T02:16:16.308Z Has data issue: false hasContentIssue false
  • English
  • Français

A Unified Model for Hysteresis in Ferroic Materials

Published online by Cambridge University Press:  01 February 2011

Stefan Seelecke  and
Ralph C. Smith
Stefan Seelecke
Affiliation:
Center for Research in Scientific Computation, North Carolina State Univ., Raleigh, NC 27695
Ralph C. Smith
Affiliation:
Center for Research in Scientific Computation, North Carolina State Univ., Raleigh, NC 27695
Get access

Abstract

This paper provides a unified modeling framework for ferroelectric, ferromagnetic and ferroelastic materials operating in hysteretic and nonlinear regimes. Whereas the physical mechanisms which produce hysteresis and constitutive nonlinearities in these materials differ at the microscopic level, shared energy relations can be derived at the lattice, or mesoscopic, scale. This yields a class of models which are appropriate for homogeneous, single crystal compounds. Stochastic homogenization techniques are then employed to construct macroscopic models suitable for nonhomogeneous, polycrystalline compounds with variable effective fields or stresses. This unified methodology for quantifying hysteresis and constitutive nonlinearities for a broad class of ferroic compounds facilitates both material characterization and subsequent model-based control design. Attributes of the models are illustrated through comparison with piezoceramic, magnetostrictive and thin film SMA data.

Keywords

Unified free energy modelshysteresisconstitutive nonlinearitiesferroic materials
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 855: Symposium W – Mechanically Active Materials , 2004 , W5.9
Copyright
Copyright © Materials Research Society 2005

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

[1] Adly, A., Mayergoyz, I. and Bergqvist, A., “Preisach modeling of magnetostrictive hysteresis,” Journal of Applied Physics, 69(8), pp. 57775779, 1991.Google Scholar
[2] Banks, H.T., Kurdila G., A.J. and Webb, G., “Identification of hysteretic control influence operators representing smart actuators Part I: Formulation,” Mathematical Problems in Engineering. 3, pp. 287328, 1997.Google Scholar
[3] Brokate, M. and Sprekels, J., Hysteresis and Phase Transitions, Springer-Verlag, New York, 1996.Google Scholar
[4] Ashhab, M., Salapaka, M.V., Dahleh, M. and Mezic, I., “Dynamical analysis and control of micro-cantilevers,” Automatica, 1999.Google Scholar
[5] Daniele, A., Salapaka, S., Salapaka, M.V. and Dahleh, M., “Piezoelectric scanners for atomic force microscopes: Design of lateral sensors, identification and control,” Proc. of the ACC, San Diego, CA, 1999 pp. 253257.Google Scholar
[6] MDapino, J., Smith, R.C., Faidley, L.E. and Flatau, A.B., “A coupled structural-magnetic strain and stress model for magnetostrictive transducers,” Journal of Intelligent Material Systems and Structures, 11(2), pp. 134152, 2000.Google Scholar
[7] Ge, P. and Jouaneh, M., “Modeling hysteresis in piezoceramic actuators,” Precision Engineering, 17, pp. 211221, 1995.Google Scholar
[8] Massad, J.E., Smith, R.C. and Carman, G.P., “A free energy model for thin-film shape memory alloys,” CRSC Technical Report CRSC-TR03–03; Proceedings of the SPIE, Smart Structures and Materials 2003, to appear.Google Scholar
[9] Mayergoyz, I.D., Mathematical Models ofHysteresis, Springer-Verlag, New York, 1991.Google Scholar
[10] Nealis, J.M. and Smith, R.C., “Robust control of a magnetostrictive actuator,” CRSC Technical Report CRSC-TR03–05; Proceedings of the SPIE, Smart Structures and Materials 2003, to appear.Google Scholar
[11] Papenfuβ, N. and Seelecke, S., “Simulation and control of SMA actuators,” Proceedings of the SPIE, Smart Structures and Materials 1999, Volume 3667, pp. 586595, 1999.Google Scholar
[12] Restorff, J.B., Savage, H.T., Clark, A.E. and Wun-Fogle, M., “Preisach modeling of hysteresis in Terfenol-D,” Journal of Applied Physics, 67(9), pp. 50165018, 1996.Google Scholar
[13] Sebastion, A. and Salapaka, S., “H00 loop shaping design for nano-positioning,” 2002 American Control Conference, to appear.Google Scholar
[14] Seelecke, S. and Müller, I., “Shape memory alloy actuators in smart structures - Modeling and simulation,” ASME AppliedMechanics Reviews, to appear.Google Scholar
[15] Smith, R.C., Dapino, M.J. and Seelecke, S., “A free energy model for hysteresis in magnetostrictive transducers,” Journal of Applied Physics, 93(1), pp. 458466, 2003.Google Scholar
[16] Smith, R.C. and Massad, J.E., “A unified methodology for modeling hysteresis in ferroic materials,” Proceedings of the 18th ASME Biennial Conference on Mechanical Vibration and Noise, 2001.Google Scholar
[17] Smith, R.C. and Ounaies, Z., “A domain wall model for hysteresis in piezoelectric materials,” Journal of Intelligent Material Systems and Structures, 11(11), pp. 6279, 2000.Google Scholar
[18] Smith, R.C., Salapaka, M.V., Hatch, A., Smith, J. and De, T., “Model development and inverse compensator design for high speed nanopositioning,” Proc. 41st IEEE Conf. Dec. and Control, 2002, Las Vegas, NV Google Scholar
[19] Smith, R.C. and Seelecke, S., “An energy formulation for Preisach models,” Proceedings of the SPIE, Smart Structures and Materials 2002, Volume 4693, pp. 173182, 2002.Google Scholar
[20] Smith, R.C., Seelecke, S. and Ounaies, Z., “A free energy model for piezoceramic materials,” Proceedings of the SPIE, Smart Structures and Materials 2002, Volume 4693, pp. 183190, 2002.Google Scholar
[21] Smith, R.C., Seelecke, S., Ounaies, Z. and Smith, J., “A free energy model for hysteresis in ferroelectric materials,” CRSC Technical Report CRSC-TR03–01; Journal of Intelligent Material Systems and Structures, submitted.Google Scholar
[22] Soukhojak, A.N. and Chiang, Y.-M.Generalized rheology of active materials,” Journal of Applied Physics, 88(11), pp. 69026909, 2000.Google Scholar
[23] Woolman, J., “Effect of atomic composition on the mechanical properties of thin film pseudoe-lastic nickel titanium,” Master's Thesis, Mechanical and Aerospace Engineering Department, UCLA, 2002 Google Scholar