Model Development for Atomic Force Microscope Stage Mechanisms

Abstract

In this paper, we develop nonlinear constitutive equations and resulting system models quantifying the nonlinear and hysteretic field-displacement relations inherent to lead zirconate titanate (PZT) devices employed in atomic force microscope stage mechanisms. We focus specifically on PZT rods utilizing d(sub 33) motion and PZT shells driven in d(sub 31) regimes, but the modeling framework is sufficiently general to accommodate a variety of drive geometries. In the first step of the model development, lattice-level energy relations are combined with stochastic homogenization techniques to construct nonlinear constitutive relations which accommodate the hysteresis inherent to ferroelectric compounds. Secondly, these constitutive relations are employed in classical rod and shell relations to construct system models appropriate for presently employed nanopositioner designs. The capability of the models to quantify the frequency-dependent hysteresis inherent to the PZT stages is illustrated through comparison with experimental data.

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Document Details

Document Type
Technical Report
Publication Date
Jan 01, 2005
Accession Number
ADA440129

Entities

People

  • Andrew G. Hatch
  • Julie K. Raye
  • Murti V. Salapaka
  • Ralph C. Smith
  • Ricardo C. Del Rosario
  • Tathagata De

Organizations

  • North Carolina State University

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Accuracy
  • Actuators
  • Amplifiers
  • Boundaries
  • Computations
  • Constitutive Equations
  • Construction
  • Domain Walls
  • Electric Fields
  • Equations
  • Ferroelectric Materials
  • Frequency
  • Geometry
  • Materials
  • Microscopes
  • Modulus Of Elasticity
  • Two Dimensional

Readers

  • Computational Fluid Dynamics (CFD)
  • Materials Science and Engineering.
  • Structural Dynamics.