Real
CHPrecipMatrixElasticity::computeQpOffDiagJacobian(unsigned int jvar)
{
  for (unsigned int i=0; i<_n_OP_vars; i++)
  {
    if (jvar == _n_var[i])
    {
      RankTwoTensor a = _elasticity_tensor[_qp]*_elastic_strain[_qp];
      RankTwoTensor b = _elasticity_tensor[_qp]*(_dn_misfit_strain[_qp])[i]*(-1);
      RankTwoTensor c = (_dn_elasticity_tensor[_qp])[i]*_elastic_strain[_qp];

      Real Jaa = a.doubleContraction( ( (_dcdn_misfit_strain[_qp])[i])*(-1) );
      Real Jab = b.doubleContraction( (_dc_misfit_strain[_qp])*(-1) );
      Real Jac = c.doubleContraction( (_dc_misfit_strain[_qp])*(-1) );

      return _scaling_factor*_phi[_j][_qp]*_test[_i][_qp]*(Jaa + Jab + Jac);
    }
  }

  if (jvar == _w_var)
    return -_phi[_j][_qp] * _test[_i][_qp];

  else if (jvar == _T_var)
    return 0;

  else
    mooseError("Screwed up CHCoupledCalphadSplit::computeQpOffDiagJacobian()");
}
Real
stzRHEVPFlowRatePowerLawJ2::computeEqvStress(const RankTwoTensor & pk2_dev, const RankTwoTensor & ce) const
{
  RankTwoTensor sdev = pk2_dev * ce;
  Real val = sdev.doubleContraction(sdev.transpose());
  return std::pow(1.0 * val, 0.5);
}
Esempio n. 3
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Real
AuxElasticEnergy::computeValue()
{
  RankTwoTensor stress = _elasticity_tensor[_qp]*_elastic_strain[_qp];

  return 0.5*stress.doubleContraction(_elastic_strain[_qp]);
}
Esempio n. 4
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Real
FlowRateModel::computeEqvStress(const RankTwoTensor & pk2_dev, const RankTwoTensor & ce) const
{
  RankTwoTensor sdev = pk2_dev * ce;
  Real val = sdev.doubleContraction(sdev.transpose());
  return std::pow(3.0 * val/2.0, 0.5);
}
Esempio n. 5
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Real
RankTwoScalarAux::computeValue()
{
    Real val;
    RankTwoTensor s;

    switch (_scalar_type)
    {
    case 0:
        s = _tensor[_qp].deviatoric();//Calculates deviatoric tensor
        val = std::pow(3.0/2.0 * s.doubleContraction(s), 0.5);//Calculates sqrt(3/2*s:s)
        break;
    case 1:
        ///For plastic strain tensor (ep), tr(ep) = 0 is considered
        val = std::pow(2.0/3.0 * _tensor[_qp].doubleContraction(_tensor[_qp]), 0.5);//Calculates sqrt(2/3*ep:ep)
        break;
    case 2:
        val = _tensor[_qp].trace()/3.0;
        break;
    case 3:
        val = _tensor[_qp].L2norm();
        break;
    case 4:
    case 5:
    case 6:
        val = calcEigenValues();
        break;
    default:
        mooseError("RankTwoScalarAux Error: Pass valid scalar type - VonMisesStress, EquivalentPlasticStrain, Hydrostatic, L2norm MaxPrincipal MidPrincipal MinPrincipal");
    }
    return val;
}
Real
CHPrecipMatrixElasticity::computeDFDC(PFFunctionType type)
{
  RankTwoTensor a = _elasticity_tensor[_qp]*(_elastic_strain[_qp]);
  RankTwoTensor b = _elasticity_tensor[_qp]*_dc_misfit_strain[_qp]*(-1);
  //in this case, dc_elasticity_tensor = 0

  Real first  = a.doubleContraction( (_dc_misfit_strain[_qp])*(-1) );
  Real second = b.doubleContraction( _elastic_strain[_qp] );

  switch(type)
  {
  case Residual:
    return _scaling_factor*0.5*(first + second);

  case Jacobian:
    return _scaling_factor*_phi[_j][_qp]*b.doubleContraction( (_dc_misfit_strain[_qp])*(-1) );
    //return 0;
  }

  mooseError("invalid type passed in");
}
Esempio n. 7
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Real
AuxChemElastic::computeDintDnoncons()
{
  RankTwoTensor d_eigenstrain;
  RankTwoTensor c;
  RankFourTensor elasticity;

  d_eigenstrain = (_precipitate_eigenstrain_rotated[_qp])[_noncons_var_num-1];
  elasticity = _precipitate_elasticity[_qp];

  c = elasticity*d_eigenstrain;

  return -2.0*c.doubleContraction(_local_strain[_qp]);
}
Esempio n. 8
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Real
AuxCalphadEnergy::computeMatrixEnergy()
{
  //Joules/meter^3
  Real chemical_energy =  ( (1 - _H)*_G_alpha[_qp] + _H*_G_delta[_qp] + _W[_qp]*_g) / _Omega[_qp];
  RankTwoTensor a = _elasticity_tensor[_qp]*(_elastic_strain[_qp]);

  Real elastic_energy = 0.5*a.doubleContraction( _elastic_strain[_qp]);

  //_console<<"matrix elastic energy = "<<elastic_energy<<std::endl;
  //_console<<"matrix chemical energy = "<<chemical_energy<<std::endl;

  return chemical_energy + elastic_energy;
}
Esempio n. 9
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Real
AuxCalphadEnergy::computeDifferential()
{
  //Joules/meter^3
  Real dfchem_dOP = ( (_G_delta[_qp] - _G_alpha[_qp])*_dH_dOP + _W[_qp]*_dg_dOP ) / _Omega[_qp];

  Real dfchem_dX = ( (1-_H)*_dG_alpha[_qp] + _H*_dG_delta[_qp] ) / _Omega[_qp];

  RankTwoTensor a = _Cijkl_MP[_qp]*_elastic_strain[_qp];
  RankTwoTensor b = _Cijkl_MP[_qp]*(_dc_misfit_strain[_qp])*(-1);

  Real e1 = a.doubleContraction( (_dc_misfit_strain[_qp])*(-1) );
  Real e2 = b.doubleContraction( _elastic_strain[_qp] );
  Real e3 = 0;

  Real dfel_dX = 0.5*(e1 + e2 + e3);

  // _console<<"dfel_dX = "<<dfel_dX<<std::endl;

  RankFourTensor dCijkl = (_Cijkl_precipitate_MP[_qp] - _Cijkl_MP[_qp])*(-1*_dH_dOP);
  b = _Cijkl_MP[_qp]*( (_dn_misfit_strain[_qp])[_OP_number-1]) *(-1);
  RankTwoTensor c = dCijkl*_elastic_strain[_qp];

  e1 = a.doubleContraction( ( (_dn_misfit_strain[_qp])[_OP_number-1] )*(-1) );
  e2 = b.doubleContraction( _elastic_strain[_qp]);
  e3 = c.doubleContraction( _elastic_strain[_qp]);

  Real dfel_dOP = 0.5*(e1 + e2 + e3);

  // _console<<"dfel_dOP = "<<dfel_dOP<<std::endl;

  Real dfdc = (dfchem_dX + dfel_dX)*(_precip_cons - _X[_qp]);

  Real dfdOP = (dfchem_dOP + dfel_dOP)*(_precip_noncons - (*_OP[_OP_number-1])[_qp]);

  return dfdc + dfdOP;
}
Esempio n. 10
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Real
AuxChemElastic::computeDselfDnoncons()
{

  RankTwoTensor eigenstrain;
  RankTwoTensor d_eigenstrain;
  RankTwoTensor c;
  RankFourTensor elasticity;

  eigenstrain = (_eigenstrains_rotated_MP[_qp])[_noncons_var_num-1];
  d_eigenstrain =( _d_eigenstrains_rotated_MP[_qp])[_noncons_var_num-1];
  elasticity = _elasticity_tensor[_qp];

  c = elasticity*eigenstrain;

  return 2.0*c.doubleContraction(d_eigenstrain);
}
Esempio n. 11
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Real
AuxCalphadEnergy::computePrecipEnergy()
{
  //this needs to be computed FOR the precipitate if it were this point...
//joules/meter^3
 Real chemical_energy = _G_delta_precip[_qp] / _Omega[_qp];

 RankTwoTensor elastic_precip_strain = _local_strain[_qp] - (_precipitate_eigenstrain[_qp])[_OP_number-1];

 RankTwoTensor a = _Cijkl_precipitate_MP[_qp]*elastic_precip_strain;

 Real elastic_energy = 0.5*a.doubleContraction( elastic_precip_strain);

 //_console<<"precip elastic energy = "<<elastic_energy<<std::endl;
 //_console<<"precip chemical energy = "<<chemical_energy<<std::endl;


 return chemical_energy + elastic_energy;
}
Esempio n. 12
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Real
AuxChemElastic::computeInteractionElasticEnergy(bool matrix)
{
  RankTwoTensor eigenstrain;
  RankTwoTensor c;
  RankFourTensor elasticity;

  if(matrix)
  {
    eigenstrain = (_eigenstrains_rotated_MP[_qp])[_noncons_var_num-1];
    elasticity = _elasticity_tensor[_qp];
  }
  else
  {
    eigenstrain = (_precipitate_eigenstrain_rotated[_qp])[_noncons_var_num-1];
    elasticity = _precipitate_elasticity[_qp];
  }

  c = elasticity*eigenstrain;

  return c.doubleContraction(_local_strain[_qp]);
}
Esempio n. 13
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RankTwoTensor
HEVPFlowRatePowerLawJ2::computePK2Deviatoric(const RankTwoTensor & pk2,
                                             const RankTwoTensor & ce) const
{
  return pk2 - (pk2.doubleContraction(ce) * ce.inverse()) / 3.0;
}
Esempio n. 14
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RankTwoTensor
testnewExampleMaterial::computePK2Deviatoric(const RankTwoTensor & pk2, const RankTwoTensor & ce) const
{
  return pk2 - (pk2.doubleContraction(ce) * ce.inverse())/3.0;
}