Ejemplo n.º 1
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    def evaluate(self, symbols_and_values_in, symbol_out):

        tensor = ElasticTensor.from_voigt(symbols_and_values_in.get('E_ij'))

        if symbol_out == 'E':
            return tensor.y_mod

        return None
Ejemplo n.º 2
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    def _evaluate(self, symbol_values):

        structure = symbol_values['structure']
        cij = symbol_values['C_ij']

        elastic_tensor = ElasticTensor.from_voigt(cij)

        debye_temp = elastic_tensor.debye_temperature(structure)

        return {'d': debye_temp}
Ejemplo n.º 3
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    def elastic_constant(self,
                         structure,
                         potential,
                         supercell=(1, 1, 1),
                         nd=0.01,
                         ns=0.05,
                         num_norm=4,
                         num_shear=4,
                         etol=1e-6,
                         ftol=1e-6,
                         nsearch=2000,
                         neval=10000):
        norm_strains = np.linspace(-nd, nd, num_norm).tolist()
        shear_strains = np.linspace(-ns, ns, num_shear).tolist()
        conventional_structure = self.conventional_structure(structure)
        deformation_set = DeformedStructureSet(conventional_structure *
                                               supercell,
                                               norm_strains=norm_strains,
                                               shear_strains=shear_strains)
        strains = []
        stresses = []

        if self.calculator_type == 'lammps':
            relax_lammps_script = load_lammps_set('relax')
            relax_lammps_script['fix'] = []
            relax_lammps_script['minimize'] = '%f %f %d %d' % (etol, ftol,
                                                               nsearch, neval)
            kwargs = {'lammps_set': relax_lammps_script}
        elif self.calculator_type == 'lammps_cython':
            kwargs = {
                'lammps_additional_commands': [
                    'min_style cg',
                    'minimize %f %f %d %d' % (etol, ftol, nsearch, neval)
                ]
            }

        async def calculate():
            futures = []
            for deformation, deformed_structure in zip(
                    deformation_set.deformations, deformation_set):
                strains.append(Strain.from_deformation(deformation))
                futures.append(await
                               self.calculator.submit(deformed_structure,
                                                      potential,
                                                      properties={'stress'},
                                                      **kwargs))
            for result in await asyncio.gather(*futures):
                stress = Stress(np.array(result['results']['stress']) *
                                1e-4)  # Convert to GPa
                stresses.append(stress)

        self._run_async_func(calculate())
        return ElasticTensor.from_independent_strains(strains, stresses,
                                                      Stress(np.zeros((3, 3))))
Ejemplo n.º 4
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def get_debye_temp(mpid):
    """
    Calculates the debye temperature from eleastic tensors on the Materials Project
    Credits: Joseph Montoya
    """
    pd.np.seterr(over="ignore") # ignore overflow in double scalars
    data = mpr.get_data(mpid)[0]
    struct = Structure.from_str(data['cif'], fmt='cif')
    c_ij = ElasticTensor.from_voigt(data['elasticity']['elastic_tensor'])
    td = c_ij.debye_temperature(struct)

    return td
Ejemplo n.º 5
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    def evaluate(self,
                 symbols_and_values_in,
                 symbol_out):

        if symbol_out == 'Cij':

            tensor = ComplianceTensor.from_voigt(symbols_and_values_in.get('Sij'))
            return tensor.elastic_tensor.voigt

        elif symbol_out == 'Sij':

            tensor = ElasticTensor.from_voigt(symbols_and_values_in.get('Cij'))
            return tensor.compliance_tensor.voigt

        return None
Ejemplo n.º 6
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    def elastic_constant(self, structure, potential, supercell=(1, 1, 1),
                         nd=0.01, ns=0.05, num_norm=4, num_shear=4,
                         etol=1e-6, ftol=1e-6, nsearch=2000, neval=10000):
        norm_strains = np.linspace(-nd, nd, num_norm).tolist()
        shear_strains = np.linspace(-ns, ns, num_shear).tolist()
        conventional_structure = self.conventional_structure(structure)
        deformation_set = DeformedStructureSet(conventional_structure * supercell,
                                               norm_strains=norm_strains,
                                               shear_strains=shear_strains)
        strains = []
        stresses = []

        if self.calculator_type == 'lammps':
            relax_lammps_script = load_lammps_set('relax')
            relax_lammps_script['fix'] = []
            relax_lammps_script['minimize'] = '%f %f %d %d' % (etol, ftol, nsearch, neval)
            kwargs = {'lammps_set': relax_lammps_script}
        elif self.calculator_type == 'lammps_cython':
            kwargs = {'lammps_additional_commands': [
                'min_style cg',
                'minimize %f %f %d %d' % (etol, ftol, nsearch, neval)
            ]}

        async def calculate():
            futures = []
            for deformation, deformed_structure in zip(deformation_set.deformations, deformation_set):
                strains.append(Strain.from_deformation(deformation))
                futures.append(await self.calculator.submit(
                    deformed_structure, potential,
                    properties={'stress'},
                    **kwargs))
            for result in await asyncio.gather(*futures):
                stress = Stress(np.array(result['results']['stress']) * 1e-4) # Convert to GPa
                stresses.append(stress)

        self._run_async_func(calculate())
        return ElasticTensor.from_independent_strains(strains, stresses, Stress(np.zeros((3, 3))))
Ejemplo n.º 7
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    subprocess.call(['lammps', '-i', 'lammps.in'],
                    cwd=deformation_directory,
                    stdout=subprocess.PIPE)

    lammps_log = LammpsLog(os.path.join(deformation_directory, 'lammps.log'))
    stress = Stress(lammps_log.get_stress(-1))

    strained_structures.append({
        'strain': strain,
        'structrure': strained_structure,
        'stress': stress / -10000.0  # bar to GPa
    })

strains = [defo['strain'] for defo in strained_structures]
stresses = [defo['stress'] for defo in strained_structures]
elastic = ElasticTensor.from_pseudoinverse(strains, stresses)

print('Stiffness Tensor')
for row in elastic.voigt:
    print(
        '{:+8.1f} {:+8.1f} {:+8.1f} {:+8.1f} {:+8.1f} {:+8.1f}\n'.format(*row))

print('Shear Modulus G_V', elastic.g_voigt)
print('Shear Modulus G_R', elastic.g_reuss)
print('Shear Modulus G_vrh', elastic.g_vrh)

print('Bulk Modulus K_V', elastic.k_voigt)
print('Bulk Modulus K_R', elastic.k_reuss)
print('Bulk Modulus K_vrh', elastic.k_vrh)

print('Elastic Anisotropy', elastic.universal_anisotropy)