Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
110 tokens/sec
GPT-4o
56 tokens/sec
Gemini 2.5 Pro Pro
44 tokens/sec
o3 Pro
6 tokens/sec
GPT-4.1 Pro
47 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

An efficient finite element method for computing the response of a strain-limiting elastic solid containing a v-notch and inclusions (2402.13409v1)

Published 20 Feb 2024 in math.NA and cs.NA

Abstract: Accurate triangulation of the domain plays a pivotal role in computing the numerical approximation of the differential operators. A good triangulation is the one which aids in reducing discretization errors. In a standard collocation technique, the smooth curved domain is typically triangulated with a mesh by taking points on the boundary to approximate them by polygons. However, such an approach often leads to geometrical errors which directly affect the accuracy of the numerical approximation. To restrict such geometrical errors, \textit{isoparametric}, \textit{subparametric}, and \textit{iso-geometric} methods were introduced which allow the approximation of the curved surfaces (or curved line segments). In this paper, we present an efficient finite element method to approximate the solution to the elliptic boundary value problem (BVP), which governs the response of an elastic solid containing a v-notch and inclusions. The algebraically nonlinear constitutive equation along with the balance of linear momentum reduces to second-order quasi-linear elliptic partial differential equation. Our approach allows us to represent the complex curved boundaries by smooth \textit{one-of-its-kind} point transformation. The main idea is to obtain higher-order shape functions which enable us to accurately compute the entries in the finite element matrices and vectors. A Picard-type linearization is utilized to handle the nonlinearities in the governing differential equation. The numerical results for the test cases show considerable improvement in the accuracy.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (58)
  1. Finite element approximation of a strain-limiting elastic model. IMA Journal of Numerical Analysis, 40(1):29–86, 2020.
  2. On elastic solids with limiting small strain: modeling and analysis. EMS Surveys in Mathematical Sciences, 1(2), 2014.
  3. Existence of solutions for the anti-plane stress for a new class of strain-limiting elastic bodies. Calculus of Variations and Partial Differential Equations, 54(2):2115–2147, 2015.
  4. Analysis and approximation of a strain-limiting nonlinear elastic model. Mathematics and Mechanics of Solids, 20(1):92–118, 2015.
  5. A novel nonlinear constitutive model for rock: Numerical assessment and benchmarking. Applications in Engineering Science, 3:100012, 2020.
  6. R. Bustamante and K. R. Rajagopal. A new type of constitutive equation for nonlinear elastic bodies. fitting with experimental data for rubber-like materials. Proceedings of the Royal Society A, 477(2252):20210330, 2021.
  7. Interpolation theory over curved elements, with applications to finite element methods. Computer Methods in Applied Mechanics and Engineering, 1(2):217–249, 1972.
  8. A thermodynamically consistent constitutive equation for describing the response exhibited by several alloys and the study of a meaningful physical problem. International Journal of Solids and Structures, 108:1–10, 2017.
  9. Curved, isoparametric,“quadrilateral” elements for finite element analysis. International Journal of Solids and Structures, 4(1):31–42, 1968.
  10. Numerical simulation of mode-iii fracture incorporating interfacial mechanics. International Journal of Fracture, 192:47–56, 2015.
  11. Modeling fracture in the context of a strain-limiting theory of elasticity: A single plane-strain crack. International Journal of Engineering Science, 88:73–82, 2015.
  12. K. Gou and S. M. Mallikarjunaiah. Computational modeling of circular crack-tip fields under tensile loading in a strain-limiting elastic solid. Communications in Nonlinear Science and Numerical Simulation, 121:107217, 2023.
  13. K. Gou and S. M. Mallikarjunaiah. Finite element study of v-shaped crack-tip fields in a three-dimensional nonlinear strain-limiting elastic body. Mathematics and Mechanics of Solids, page 10812865231152257, 2023.
  14. Super-elastic titanium alloy with unstable plastic deformation. Applied Physics Letters, 87(9):091906, 2005.
  15. V. Kesavulu Naidu and K. V. Nagaraja. The use of parabolic arc in matching curved boundary by point transformations for septic order triangular element and its applications. Advanced Studies in Contemporary Mathematics, 20(3):437–456, 2010.
  16. V. Kesavulu Naidu and K. V. Nagaraja. Advantages of cubic arcs for approximating curved boundaries by subparametric transformations for some higher order triangular elements. Applied Mathematics and Computation, 219(12):6893–6910, 2013.
  17. A finite strain elastic-viscoplastic model of gum metal. International Journal of Plasticity, 119:85–101, 2019.
  18. Anti-plane stress state of a plate with a v-notch for a new class of elastic solids. International Journal of Fracture, 179(1):59–73, 2013.
  19. Modeling gum metal and other newly developed titanium alloys within a new class of constitutive relations for elastic bodies. Archives of Mechanics, 69(3), 2017.
  20. The state of stress and strain adjacent to notches in a new class of nonlinear elastic bodies. Journal of Elasticity, 135(1):375–397, 2019.
  21. Finite element simulation of quasi-static tensile fracture in nonlinear strain-limiting solids with the phase-field approach. Journal of Computational and Applied Mathematics, 399:113715, 2022.
  22. T. Mai and J. R. Walton. On monotonicity for strain-limiting theories of elasticity. Journal of Elasticity, 120(1):39–65, 2015.
  23. T. Mai and J. R. Walton. On strong ellipticity for implicit and strain-limiting theories of elasticity. Mathematics and Mechanics of Solids, 20(2):121–139, 2015.
  24. S. M. Mallikarjunaiah. On Two Theories for Brittle Fracture: Modeling and Direct Numerical Simulations. PhD thesis, Texas A&M University, 2015.
  25. S. M. Mallikarjunaiah and D. Bhatta. A finite element model for hydro-thermal convective flow in a porous medium: Effects of hydraulic resistivity and thermal diffusivity. Under review, 2023.
  26. On the direct numerical simulation of plane-strain fracture in a class of strain-limiting anisotropic elastic bodies. International Journal of Fracture, 192(2):217–232, 2015.
  27. The use of parabolic arcs in matching curved boundaries in the finite element method. IMA Journal of Applied Mathematics, 16(2):239–246, 1975.
  28. A. R. Mitchell. Advantages of cubics for approximating element boundaries. Computers & Mathematics with Applications, 5(4):321–327, 1979.
  29. Determining material properties of natural rubber using fewer material moduli in virtue of a novel constitutive approach for elastic bodies. Rubber Chemistry and Technology, 91(2):375–389, 2018.
  30. Darcy–brinkman–forchheimer flow over irregular domain using finite elements method. IOP Conference Series: Materials Science and Engineering, 577(1):012158, nov 2019.
  31. Solution of darcy-brinkman flow over an irregular domain by finite element method. Journal of Physics: Conference Series, 1172(1):012091, mar 2019.
  32. Solution of darcy–brinkman–forchheimer equation for irregular flow channel by finite elements approach. Journal of Physics: Conference Series, 1172(1):012033, mar 2019.
  33. The use of parabolic arc in matching curved boundary by point transformations for sextic order triangular element. International Journal of Mathematical Analysis, 4:357–374, 2010.
  34. R. W. Ogden. Large deformation isotropic elasticity–on the correlation of theory and experiment for incompressible rubberlike solids. Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences, 326(1567):565–584, 1972.
  35. K. R. Rajagopal. On implicit constitutive theories. Applications of Mathematics, 48(4):279–319, 2003.
  36. K. R. Rajagopal. The elasticity of elasticity. Zeitschrift für Angewandte Mathematik und Physik (ZAMP), 58(2):309–317, 2007.
  37. K. R. Rajagopal. Conspectus of concepts of elasticity. Mathematics and Mechanics of Solids, 16(5):536–562, 2011.
  38. K. R. Rajagopal. Non-linear elastic bodies exhibiting limiting small strain. Mathematics and Mechanics of Solids, 16(1):122–139, 2011.
  39. K. R. Rajagopal. On the nonlinear elastic response of bodies in the small strain range. Acta Mechanica, 225(6):1545–1553, 2014.
  40. On thermomechanical restrictions of continua. Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, 460(2042):631–651, 2004.
  41. On a class of non-dissipative materials that are not hyperelastic. In Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences, volume 465, pages 493–500. The Royal Society, 2009.
  42. Modeling fracture in the context of a strain-limiting theory of elasticity: a single anti-plane shear crack. International journal of fracture, 169(1):39–48, 2011.
  43. KR Rajagopal and A. R. Srinivasa. On the response of non-dissipative solids. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 463(2078):357–367, 2007.
  44. The use of parabolic arcs in matching curved boundaries by point transformations for some higher order triangular elements. Finite Elements in Analysis and Design, 44(15):920–932, 2008.
  45. Multifunctional alloys obtained via a dislocation-free plastic deformation mechanism. Science, 300(5618):464–467, 2003.
  46. On an efficient octic order sub-parametric finite element method on curved domains. Computers & Mathematics with Applications, 143:249–268, 2023.
  47. L. R. Scott. Finite element techniques for curved boundaries. PhD thesis, Massachusetts Institute of Technology, 1973.
  48. Improved finite element triangular meshing for symmetric geometries using matlab. Materials Today: Proceedings, 46:4375–4380, 2021.
  49. Finite element method to solve poisson’s equation using curved quadratic triangular elements. IOP Conference Series: Materials Science and Engineering, 577(1):012165, nov 2019.
  50. Two-dimensional non-uniform mesh generation for finite element models using matlab. Materials Today: Proceedings, 46:3037–3043, 2021. International Conference on Advances in Material Science and Chemistry – 2020 (ICAMSC-2020).
  51. Nonlinear elastic behavior induced by nano-scale α𝛼\alphaitalic_α phase in β𝛽\betaitalic_β matrix of β𝛽\betaitalic_β-type ti–25nb–3zr–2sn–3mo titanium alloy. Materials Letters, 145:283–286, 2015.
  52. M. Vasilyeva and S. M. Mallikarjunaiah. Generalized multiscale finite element treatment of a heterogeneous nonlinear strain-limiting elastic model. Multiscale Modeling & Simulation, 22(1):334–368, 2024.
  53. Multiscale model reduction technique for fluid flows with heterogeneous porous inclusions. Journal of Computational and Applied Mathematics, 424:114976, 2023.
  54. Quasi-static anti-plane shear crack propagation in nonlinear strain-limiting elastic solids using phase-field approach. International Journal of Fracture, 227(2):153–172, 2021.
  55. A finite-element discretization of some boundary value problems for nonlinear strain-limiting elastic bodies. Mathematics and Mechanics of Solids, 27(2):281–307, 2022.
  56. Finite element solution of crack-tip fields for an elastic porous solid with density-dependent material moduli and preferential stiffness. Accepted for publication in Advances in Mechanical Engineering, 2024.
  57. Finite element model for a coupled thermo-mechanical system in nonlinear strain-limiting thermoelastic body. Communications in Nonlinear Science and Numerical Simulation, 108:106262, 2022.
  58. The finite element method for solid and structural mechanics. Elsevier, 2005.
User Edit Pencil Streamline Icon: https://streamlinehq.com
Authors (4)
  1. Shylaja G. (1 paper)
  2. Kesavulu Naidu V. (1 paper)
  3. Venkatesh B. (1 paper)
  4. S. M. Mallikarjunaiah (13 papers)

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now