Started adding mdr model to pair_granular.rst

2025-01-03 17:43:38 -05:00
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--- a/doc/src/pair_granular.rst
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@ -82,6 +82,7 @@ and their required arguments are:
 3. *hertz/material* : E, :math:`\eta_{n0}` (or :math:`e`), :math:`\nu`
 4. *dmt* : E, :math:`\eta_{n0}` (or :math:`e`), :math:`\nu`, :math:`\gamma`
 5. *jkr* : E, :math:`\eta_{n0}` (or :math:`e`), :math:`\nu`, :math:`\gamma`
 6. *mdr* : :math:`E`, :math:`\nu`, :math:`Y`, :math:`\Delta\gamma`, :math:`\psi_b`, :math:`e`
 Here, :math:`k_n` is spring stiffness (with units that depend on model
 choice, see below); :math:`\eta_{n0}` is a damping prefactor (or, in its
@ -162,6 +163,45 @@ initially will not experience force until they come into contact
 experience a tensile force up to :math:`3\pi\gamma R`, at which point they
 lose contact.
 The *mdr* model is a mechanically-derived contact model able to capture the 
 contact response between adhesive elastic-plastic particles into large deformation.
 The inputs to the model are primarily physical material 
 properties: Young's Modulus :math:`E`, Poisson's ratio :math:`\nu`,
 yield stress :math:`Y`, effective surface energy :math:`\Delta\gamma`, and 
 coefficent of restitution :math:`e`. The execption is the critical confinement 
 ratio :math:`\psi_b` which is a geometrically motivated criterion for determining 
 when the bulk elastic response will trigger. The adhesive response is based on
 a JKR-type fracture mechanics based formulation that is valid into large deformation.     
 The majority of the theoritical foundations of the *mdr* model are developed in the
 two part series :ref:`Zunker and Kamrin Part I <Zunker2024I>` and 
 :ref:`Zunker and Kamrin Part II <Zunker2024II>`. Additional development 
 of the model and demonstration of its ability to simulate industrially relavant 
 powder compaction processes are presented in :ref:`Zunker et al. <Zunker2025>`
 .. note::
   The *mdr* model requires some specific settings to function properly,
   please read the following text carefully to ensure all requirments are 
   followed.
 Newton's third law must be set *off*. This ensures that the neighbor lists
 are constructed properly for the topological penalty algorithm used to screen
 for non-physical contacts occurring through obstructing particles, an issue
 prevelant under large deformation conditions. For more information on this
 algorithm see :ref:`Zunker et al. <Zunker2025>`
 .. code-block:: LAMMPS
   newton off
 The damping model must be set to *none*. The *mdr* model already has a built 
 in damping model. 
 .. code-block:: LAMMPS
   pair_coeff * * mdr 5e6 0.4 1.9e5 2 0.5 0.5 damping none
 ----------
 In addition, the normal force is augmented by a damping term of the
@ -870,6 +910,28 @@ solids. Proc. R. Soc. Lond. A, 324(1558), 301-313.
 Y. P. (1975). Effect of contact deformations on the adhesion of
 particles. Journal of Colloid and interface science, 53(2), 314-326.
 .. _Zunker2024I:
 **(Zunker et al, 2024)** Zunker, W., & Kamrin, K. (2024).
 A mechanically-derived contact model for adhesive elastic-perfectly
 plastic particles, Part I: Utilizing the method of dimensionality
 reduction. Journal of the Mechanics and Physics of Solids, 183, 105492.
 .. _Zunker2024II:
 **(Zunker et al, 2024)** Zunker, W., & Kamrin, K. (2024).
 A mechanically-derived contact model for adhesive elastic-perfectly
 plastic particles, Part II: Contact under high compaction—modeling
 a bulk elastic response. Journal of the Mechanics and Physics of Solids,
 183, 105493.
 .. _Zunker2025:
 **(Zunker et al, 2025)** Zunker, W., Dunatunga, S., Thakur, S.,
 Tang, P., & Kamrin, K. (2025). Experimentally validated DEM for large
 deformation powder compaction: mechanically-derived contact model and
 screening of non-physical contacts. engrXiv.
 .. _Luding2008:
 **(Luding, 2008)** Luding, S. (2008). Cohesive, frictional powders: