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Theory of dielectric elastomers

Theory of dielectric elastomers. Zhigang Suo Harvard University 11:15 am – 12:00 noon, 11 January 2010, Monday PhD Winter School Dielectric Elastomer Transducers Monte Verita, Ascona, Switzerland, 11-16 January 2010 http://www.empa.ch/eap-winterschool. Dielectric elastomer.

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Theory of dielectric elastomers

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  1. Theory of dielectric elastomers Zhigang Suo Harvard University 11:15 am – 12:00 noon, 11 January 2010, Monday PhD Winter School Dielectric Elastomer Transducers Monte Verita, Ascona, Switzerland, 11-16 January 2010 http://www.empa.ch/eap-winterschool

  2. Dielectric elastomer Reference State Current State Dielectric Elastomer Compliant Electrode Pelrine, Kornbluh, Pei, Joseph High-speed electrically actuated elastomers with strain greater than 100%. Science 287, 836 (2000).

  3. Parallel-plate capacitor P battery electrode vacuum electrode P force Electric field e0, permittivity of vacuum Electric displacement field Maxwell stress stress field

  4. - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + - + + + + + + + + + Maxwell stress Electrostriction Trouble with Maxwell stress in dielectrics Our complaints: • In general, e varies with deformation. • In general, E2 dependence has no special significance. • Wrong sign?

  5. An atom in an electric field - - - - - - - - - - - - battery Hydrogen atom + + + + + + + + + • External electric field displaces positive and negative charges somewhat. • Polarization: Induce more charge on the electrodes. • Deformation: Distort the shape of the electron cloud.

  6. A dipole in an electric field - - - - - - - - - - - - battery Polar molecules + + + + + + + + + • External electric field reorients dipoles. • Polarization: Induce more charge on the electrodes. • Deformation: Distort the shape of the sample.

  7. Field equations in vacuum, Maxwell (1873) Electrostatic field A field of forces maintain equilibrium of a field of charges P Maxwell stress P

  8. Include Maxwell stress in force balance “Free-body” diagram h

  9. James Clerk Maxwell (1831-1879) “I have not been able to make the next step, namely, to account by mechanical considerations for these stresses in the dielectric. I therefore leave the theory at this point…” A Treatise on Electricity & Magnetism (1873), Article 111

  10. Trouble with electric force in dielectrics In a vacuum, external force is needed to maintain equilibrium of charges +Q +Q P P In a solid dielectric, force between charges is NOT an operational concept +Q +Q

  11. The Feynman Lectures on PhysicsVolume II, p.10-8 (1964) “It is a difficult matter, generally speaking, to make a unique distinction between the electrical forces and mechanical forces due to solid material itself. Fortunately, no one ever really needs to know the answer to the question proposed. He may sometimes want to know how much strain there is going to be in a solid, and that can be worked out. But it is much more complicated than the simple result we got for liquids.”

  12. All troubles are gone if we use measurable quantities Current State Reference State equilibrate elastomer and loads Nominal divide by volume name quantities True equations of state Suo, Zhao, Greene,J. Mech. Phys. Solids 56, 467 (2008)

  13. VHB 4910 Dielectric constant is insensitive to stretch Kofod, Sommer-Larsen, Kornbluh, Pelrine Journal of Intelligent Material Systems and Structures 14, 787 (2003).

  14. Ideal dielectric elastomer Dielectric behavior is liquid-like, unaffected by deformation. Elasticity Polarization incompressibility For an ideal dielectric elastomer, electromechanical coupling is purely a geometric effect:

  15. Ideal dielectric elastomer In terms of nominal quantities In terms of true quantities

  16. Maxwell stress represented in three ways Reference State Current State Dielectric Elastomer Compliant Electrode biaxial stress triaxial stress Uniaxial stress For incompressible material, the 3 states of stress give the same deformation

  17. - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + - + + + + + + + + + Maxwell stress Electrostriction Electrostriction

  18. Non-ideal dielectric elastomer Dielectric constant Area ratio deformation affects dielectric constant Wissler, Mazza, Sens. Actuators, A 138, 384 (2007).

  19. Quasi-linear dielectric elastomer Zhao, Suo, JAP 104, 123530 (2008)

  20. The nominal vs. the true Reference State Current State Nominal electric field and nominal electric displacement are work-conjugate Battery does work True electric field and true electric displacement are NOT work-conjugate Battery does work

  21. Extend the theory to general loads

  22. Current State Reference State Ideal dielectric elastomer Incompressibility Elastic energy density Equations of state

  23. Incompressibility Neo-Hookean model Elastic energy density Equations of state

  24. Extend the theory to inhomogeneous field

  25. A field of markers: stretch l L Reference state Current state X x(X, t) X+dX x(X+dX, t)

  26. A field of batteries: electric field Reference state Current state L l x(X, t) x(X+dX, t) X X+dX ground

  27. 3D inhomogeneous field Condition of equilibrium Need to specify a material model

  28. PDEs Toupin (1956), Eringen (1963), Tiersten (1971), Goulbourne, Mockensturm and Frecker (2005), Dorfmann & Ogden (2005), McMeeking & Landis (2005)… Suo, Zhao, Greene, J. Mech. Phys. Solids 56, 467 (2008)

  29. The nominal vs the true Reference State Current State

  30. Ideal dielectric elastomers Liquid-like dielectric behavior, unaffected by deformation Stretch Polarization Ideal electromechanical coupling is purely a geometric effect: Zhao, Hong, Suo, Physical Review B 76, 134113 (2007)

  31. Finite element method Solve for Legendre transformation Conditions of thermodynamic equilibrium

  32. Simple Layer Ring Sphere States of equilibrium Zhao and Suo, APL 93, 251902 (2008)

  33. Oscillating Balloon Excitation by sinusoidal voltage Oscillation of the balloon Zhao and Suo, APL 93, 251902 (2008) Zhu, Cai, Suo, http://www.seas.harvard.edu/suo/papers/216.pdf

  34. Summary • Ideal dielectric elastomer: dielectric behavior is liquid-like. • Only for ideal dielectric elastomer, the Maxwell stress is valid. • A more general model can represent both the Maxwell stress and electrostriction. • Inhomogeneous, time-dependent field can also be modeled.

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