Exemple #1
0
def SigmaCoherent(T,
                  x0,
                  db,
                  comps,
                  phasenames,
                  purevms,
                  intervms=[],
                  limit=[0, 1.0],
                  dx=0.01,
                  P=1E5,
                  setverb=False):
    """
    Calculate the coherent interfacial energy in alloys.

    Parameters
    -----------
    T: float
        Given temperatur
    x0: list
        Initial alloy composition.
    db : Database
        Database containing the relevant parameters.
    comps : list
        Names of components to consider in the calculation.
    phasenames : list
        Names of phase model to build.    
    limit: list
        The limit of composition for searching interfacial composition in equilibrium.
    purevms: list
        The molar volumes of pure components.
    dx: float
        The step of composition for searching interfacial composition in equilibrium.

    Returns:   
    -----------
    Components:list of str
        Given components.
    Temperature: float
        Given temperature.
    Initial_Alloy_Composition: list
        Given initial alloy composition.
    Interfacial_Composition: list
        Interfacial composition of the grid minimization.
    Partial_Interfacial_Energies: list
        Partial interfacial energies of components.
    Interfacial_Energy: float    
        Requested interfacial energies.

    Return type: xarray Dataset
    """
    phasevm = [
        MolarVolume(Database(db), phasenames[i], list(comps), purevms[i])
        for i in range(2)
    ]  #### ASK ???????????????????????

    _vmis = InterficialMolarVolume(*phasevm)
    """decorate the _vmis to release the constains on temperature"""
    vmis = [wraptem(T, f) for f in _vmis]

    model = CoherentGibbsEnergy_PyOC(T, P, db, comps, phasenames, setverb)
    model.readDatabase()
    model.multiPhaseAnalysis()
    """Chemical potentials in two-phase equilibrium"""
    mueq = model.chemicalpotential(x0)
    """Chemical potentials in two bulk phases"""
    model_phase = [
        CoherentGibbsEnergy_PyOC(T, P, db, comps, phasenames[i], setverb)
        for i in range(len(phasenames))
    ]
    alphafuncs, betafuncs = [each.chemicalpotential for each in model_phase]

    sigma_model = SigmaCoherentInterface(alphafuncs, betafuncs, mueq, vmis,
                                         comps)

    components = [each for each in comps if each != "VA"]
    cum = int(len(components) - 1)
    print(
        "\n******************************************************************************\nOpenIEC is looking for interfacial equilibirium coposition.\nFor more information visit http://....../openiec."
    )
    x_s = SearchEquilibrium(sigma_model.objective, [limit] * cum, [dx] * cum)
    x_c = ComputeEquilibrium(sigma_model.objective, x_s["x"])
    print(
        "******************************************************************************\n\n"
    )
    sigma = sigma_model.infenergy(x_c)
    print(sigma)

    xx0 = [1.0 - sum(list(x0.values()))] + list(x0.values())
    xx_c = [1.0 - sum(list(x_c))] + list(x_c)
    sigmapartial = list(np.array(sigma).flatten())
    sigmaavg = np.average(sigma)

    res = Dataset({
        "Components": components,
        "Temperature": T,
        "Initial_Alloy_Composition": ("Components", xx0[1:]),
        "Interfacial_Composition": ("Components", xx_c),
        "Partial_Interfacial_Energy": ("Components", sigmapartial),
        "Interfacial_Energy": sigmaavg
    })

    return res
def SigmaCoherent_OC(T,
                     x0,
                     db,
                     comps,
                     phasenames,
                     purevms,
                     limit=[0, 1.0],
                     bulkX=None,
                     dx=0.01,
                     enforceGridMinimizerForLocalEq=False,
                     mueq=None):
    """
    Calculate the coherent interfacial energy in alloys.

    Parameters
    -----------
    T: float
        Given temperature.
    x0: list
        Initial alloy composition.
    db : Database
        Database containing the relevant parameters.
    comps : list
        Names of components to consider in the calculation.
    phasenames : list
        Names of phase model to build.
    purevms: list
        The molar volumes of pure components (expression) or the interfacial molar volumes (functions)
    limit: list
        The limit of composition for searching interfacial composition in equilibrium.
    bulkX: list of list
        The list of compositions of the bulk phases in equilibrium.
    dx: float
        The step of composition for searching interfacial composition in equilibrium.
    enforceGridMinimizerForLocalEq: boolean
        A flag to enforce the use of the gridminimzer in the calculation of the chemical potential of the interface for a given component composition
    mueq: list
        Bulk chemical potential for the different components

    Returns:
    -----------
    Components:list of str
        Given components.
    Temperature: float
        Given temperature.
    Initial_Alloy_Composition: list
        Given initial alloy composition.
    Interfacial_Composition: list
        Interfacial composition of the grid minimization.
    Partial_Interfacial_Energies: list
        Partial interfacial energies of components.
    Interfacial_Energy: float
        Requested interfacial energies.

    Return type: xarray Dataset
    """
    if (type(purevms[0]) == list):
        # the molar volumes of pure components are given as expressions (original openIEC implementation)
        phasevm = [
            MolarVolume(Database(db), phasenames[i], comps, purevms[i])
            for i in range(2)
        ]
        _vmis = InterficialMolarVolume(*phasevm)
        """decorate the _vmis to release the constains on temperature"""
        vmis = [wraptem(T, f) for f in _vmis]
    else:
        # the molar volumes of pure components directly given as functions
        vmis = purevms
    """Chemical potentials in two-phase equilibrium"""
    if (mueq == None):
        CoherentGibbsEnergy_OC.initOC(db, comps)
        model = CoherentGibbsEnergy_OC(T, 1E5, phasenames)
        mueq = model.chemicalpotential(x0)
    """Chemical potentials in two bulk phases"""
    CoherentGibbsEnergy_OC.initOC(db, comps)
    model_phase = [
        CoherentGibbsEnergy_OC(T, 1E5, phasenames[i], False,
                               enforceGridMinimizerForLocalEq)
        for i in range(len(phasenames))
    ]
    alphafuncs, betafuncs = [each.chemicalpotential for each in model_phase]

    sigma_model = SigmaCoherentInterface(alphafuncs, betafuncs, mueq, vmis)

    components = [each for each in comps if each != "VA"]
    cum = int(len(components) - 1)
    print(
        "\n******************************************************************************\nOpenIEC is looking for interfacial equilibirium composition with OpenCalphad.\nFor more information visit https://github.com/niamorelreillet/openiec_with_OC."
    )
    limits = limit.copy()
    if (type(limits[0]) != list):
        limits = [limits] * cum
    x_s = SearchEquilibrium(sigma_model.objective, limits, [dx] * cum, bulkX)
    x_c = ComputeEquilibrium(sigma_model.objective, x_s["x"])

    print(
        "******************************************************************************\n"
    )
    sigma = sigma_model.infenergy(x_c)

    xx0 = [1.0 - sum(list(x0))] + list(x0)
    xx_c = [1.0 - sum(list(x_c))] + list(x_c)
    sigmapartial = list(np.array(sigma).flatten())
    sigmaavg = np.average([each for each in sigma])

    res = Dataset({
        "Components": components,
        "Temperature": T,
        "Initial_Alloy_Composition": ("Components", xx0),
        "Interfacial_Composition": ("Components", xx_c),
        "Partial_Interfacial_Energy": ("Components", sigmapartial),
        "Interfacial_Energy": sigmaavg,
    })

    return res
Exemple #3
0
def SigmaSolLiq(
    T,
    x0,
    db,
    comps,
    phasenames,
    purevms,
    intervms=[],
    omega=[],
    meltingenthalpy=[],
    sigma0=[],
    xeq=[],
    limit=[0, 1.0],
    dx=0.01,
):
    """
    Calculate the solid/liquid interfacial energy in alloys.

    Parameters
    -----------
    T: float
        Given temperature.
    x0: list
        Initial alloy composition.
    db : Database
        Database containing the relevant parameters.
    comps : list
        Names of components to consider in the calculation.
    phasenames : list
        Names of phase model to build.    
    purevms: list 
        The molar volume of the components.
        example:
            comps = ["NI", "AL"] 
            phasenames = ["FCC_A1", "LIQUID"]
            purevms = [["1.0*T", "2.0*T"], ["3.0*T", "4.0*T"]]
            where "1.0*T" and "2.0*T" are molar volumes of components Ni and Al in FCC_A1 phase, while "3.0*T" and "4.0*T" are molar volumes of components Ni and Al in LIQUID phase.
    omega: list
        The molar interfacial areas of components.
    meltingenthalpy: list
        The stardard melting enthalpies of pure componnets.
    sigma0: list
        Interfacial energies of pure metal.
    xeq: list
        Two-phase equilibrium composition.
    limit: list
        The limit of composition for searching interfacial composition in equilibrium.
    dx: float
        The step of composition for searching interfacial composition in equilibrium.

    Returns:   
    -----------
    Components:list of str
        Given components.
    Temperature: float
        Given temperature.
    Initial_Alloy_Composition: list
        Given initial alloy composition.
    Interfacial_Composition: list
        Interfacial composition of the grid minimization.
    Partial_Interfacial_Energies: list
        Partial interfacial energies of components.
    Interfacial_Energy: float    
        Requested interfacial energies.

    Return type: xarray Dataset
    """

    phasevm = [
        MolarVolume(db, phasenames[i], comps, purevms[i]) for i in range(2)
    ]
    _vmis = InterficialMolarVolume(*phasevm)
    """Decorate the _vmis to release the constains on temperature"""
    vmis = [wraptem(T, f) for f in _vmis]
    """Calculation for the solid/liquid interfacial energies of pure components"""
    if not omega:
        omega = [
            MolarInterfacialArea(vmis[i](x0)) for i in range(len(comps))
            if comps[i] != "VA"
        ]

    if not (sigma0 and meltingenthalpy):
        sigma0 = [
            float(
                SigmaPure(T, vmis[i](x0), db, comps[i],
                          phasenames).Interfacial_Energy.values)
            for i in range(len(comps)) if comps[i] != "VA"
        ]

    if not sigma0 and meltingenthalpy:
        sigma0 = [
            float(
                SigmaPure(T, vmis[i](x0), db, comps[i], phasenames,
                          meltingenthalpy[i]).Interfacial_Energy.values)
            for i in range(len(comps)) if comps[i] != "VA"
        ]
    """Two-phase equilibirium composition"""
    if not xeq:
        _modeleq = CoherentGibbsEnergy(T, db, comps, phasenames)
        xeq = _modeleq.molefraction(x0)
    """Partial excess Gibbs energy in the interface """
    _modelinterface = InterfacialGibbsEnergy(T, db, comps, phasenames)
    interfacialpexgm = _modelinterface.lam_pexgm
    """Partial excess Gibbs energies in two bulk phases """
    _modelphase = [
        SolutionGibbsEnergy(T, db, comps, phasenames[i])
        for i in range(len(phasenames))
    ]
    phasepexgm = [each.lam_pexgm for each in _modelphase]
    """Call the module of solid/liquid interfacial energy calculation"""
    Model = SigmaSolidLiquidInterface(T, xeq[0], xeq[1], omega, sigma0,
                                      interfacialpexgm, phasepexgm[0],
                                      phasepexgm[1])

    components = [each for each in comps if each != "VA"]
    cum = int(len(components) - 1)
    print(
        "\n******************************************************************************\nOpenIEC is looking for interfacial equilibirium coposition.\nFor more information visit https://github.com/openiec/openiec."
    )
    x_s = SearchEquilibrium(Model.objective, [limit] * cum, [dx] * cum)
    x_c = ComputeEquilibrium(Model.objective, x_s["x"])
    print(
        "******************************************************************************\n\n"
    )
    sigma = Model.infenergy(x_c)

    xx0 = [1.0 - sum(x0)] + x0
    xx_c = [1.0 - sum(list(x_c))] + list(x_c)
    sigmapartial = list(np.array(sigma).flatten())
    sigmaavg = np.average([each for each in sigma])

    res = Dataset({
        "Components": components,
        "Temperature": T,
        "Initial_Alloy_Composition": ("Components", xx0),
        "Interfacial_Composition": ("Components", xx_c),
        "Partial_Interfacial_Energy": ("Components", sigmapartial),
        "Interfacial_Energy": sigmaavg,
    })

    return res