---
res:
  bibo_abstract:
  - We present an extension to Lagrangian finite element methods to allow for large
    plastic deformations of solid materials. These behaviors are seen in such everyday
    materials as shampoo, dough, and clay as well as in fantastic gooey and blobby
    creatures in special effects scenes. To account for plastic deformation, we explicitly
    update the linear basis functions defined over the finite elements during each
    simulation step. When these updates cause the basis functions to become ill-conditioned,
    we remesh the simulation domain to produce a new high-quality finite-element mesh,
    taking care to preserve the original boundary. We also introduce an enhanced plasticity
    model that preserves volume and includes creep and work hardening/softening. We
    demonstrate our approach with simulations of synthetic objects that squish, dent,
    and flow. To validate our methods, we compare simulation results to videos of
    real materials.@eng
  bibo_authorlist:
  - foaf_Person:
      foaf_givenName: Adam
      foaf_name: Bargteil, Adam
      foaf_surname: Bargteil
  - foaf_Person:
      foaf_givenName: Christopher J
      foaf_name: Wojtan, Christopher J
      foaf_surname: Wojtan
      foaf_workInfoHomepage: http://www.librecat.org/personId=3C61F1D2-F248-11E8-B48F-1D18A9856A87
    orcid: 0000-0001-6646-5546
  - foaf_Person:
      foaf_givenName: Jessica
      foaf_name: Hodgins, Jessica
      foaf_surname: Hodgins
  - foaf_Person:
      foaf_givenName: Greg
      foaf_name: Turk, Greg
      foaf_surname: Turk
  bibo_doi: 10.1145/1276377.1276397
  bibo_issue: '3'
  bibo_volume: 26
  dct_date: 2007^xs_gYear
  dct_language: eng
  dct_publisher: ACM@
  dct_title: A finite element method for animating large viscoplastic flow@
...