6533b835fe1ef96bd129f47d
RESEARCH PRODUCT
Stress gradient versus strain gradient constitutive models within elasticity
Castrenze Polizzottosubject
Boundary conditionsInternal energyDifferential equationMechanical EngineeringApplied MathematicsConstitutive equationMathematical analysisElasticity (physics)Condensed Matter PhysicsGibbs free energysymbols.namesakeMaterials Science(all)Beam modelsVariational principleMechanics of MaterialsModeling and SimulationModelling and SimulationsymbolsStress gradient elasticityGeneral Materials ScienceBoundary value problemPrinciple of the virtual powerBeam (structure)Mathematicsdescription
Abstract A stress gradient elasticity theory is developed which is based on the Eringen method to address nonlocal elasticity by means of differential equations. By suitable thermodynamics arguments (involving the free enthalpy instead of the free internal energy), the restrictions on the related constitutive equations are determined, which include the well-known Eringen stress gradient constitutive equations, as well as the associated (so far uncertain) boundary conditions. The proposed theory exhibits complementary characters with respect to the analogous strain gradient elasticity theory. The associated boundary-value problem is shown to admit a unique solution characterized by a Hellinger–Reissner type variational principle. The main differences between the Eringen stress gradient model and the concomitant Aifantis strain gradient model are pointed out. A rigorous formulation of the stress gradient Euler–Bernoulli beam is provided; the response of this beam model is discussed as for its sensitivity to the stress gradient effects and compared with the analogous strain gradient beam model.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2014-05-01 | International Journal of Solids and Structures |