Info<< "Reading field U\n" << endl; volVectorField U ( IOobject ( "U", runTime.timeName(), mesh, IOobject::MUST_READ, IOobject::AUTO_WRITE ), mesh ); volTensorField gradU = fvc::grad(U); volSymmTensorField epsilon ( IOobject ( "epsilon", runTime.timeName(), mesh, IOobject::READ_IF_PRESENT, IOobject::AUTO_WRITE ), mesh, dimensionedSymmTensor("zero", dimless, symmTensor::zero) ); Info<< "Reading field T\n" << endl; volScalarField T ( IOobject ( "T", runTime.timeName(), mesh, IOobject::MUST_READ, IOobject::AUTO_WRITE ), mesh ); volSymmTensorField sigma ( IOobject ( "sigma", runTime.timeName(), mesh, IOobject::READ_IF_PRESENT, IOobject::AUTO_WRITE ), mesh, dimensionedSymmTensor("zero", dimForce/dimArea, symmTensor::zero) ); volVectorField sigmaExp ( IOobject ( "sigmaExp", runTime.timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE ), mesh, dimensionedVector("zero", dimensionSet(1,-2,-2,0,0,0,0), vector::zero) ); //- mechanical properties rheologyModel rheology(sigma); volScalarField rho = rheology.rho(); volScalarField mu = rheology.mu(); volScalarField lambda = rheology.lambda(); surfaceScalarField muf = fvc::interpolate(mu, "mu"); surfaceScalarField lambdaf = fvc::interpolate(lambda, "lambda"); surfaceVectorField n = mesh.Sf()/mesh.magSf(); //- thermal properties Info<< "Reading thermal properties\n" << endl; thermalModel thermal(T); volScalarField C = thermal.C(); volScalarField k = thermal.k(); volScalarField threeKalpha = rheology.threeK()*rho*thermal.alpha(); volScalarField T0 = thermal.T0(); volScalarField rhoC = rho*C;