"""Function-like objects creating cubic lattices (SC, FCC, BCC and Diamond). The following lattice creators are defined: SimpleCubic FaceCenteredCubic BodyCenteredCubic Diamond """ from ase.lattice.bravais import Bravais import numpy as np from ase.data import reference_states as _refstate class SimpleCubicFactory(Bravais): "A factory for creating simple cubic lattices." # The name of the crystal structure in ChemicalElements xtal_name = "sc" # The natural basis vectors of the crystal structure int_basis = np.array([[1, 0, 0], [0, 1, 0], [0, 0, 1]]) basis_factor = 1.0 # Converts the natural basis back to the crystallographic basis inverse_basis = np.array([[1, 0, 0], [0, 1, 0], [0, 0, 1]]) inverse_basis_factor = 1.0 # For checking the basis volume atoms_in_unit_cell = 1 def get_lattice_constant(self): "Get the lattice constant of an element with cubic crystal structure." if _refstate[self.atomicnumber]['symmetry'].lower() != self.xtal_name: raise ValueError, (("Cannot guess the %s lattice constant of" + " an element with crystal structure %s.") % (self.xtal_name, _refstate[self.atomicnumber]['symmetry'])) return _refstate[self.atomicnumber]['a'] def make_crystal_basis(self): "Make the basis matrix for the crystal unit cell and the system unit cell." self.crystal_basis = (self.latticeconstant * self.basis_factor * self.int_basis) self.miller_basis = self.latticeconstant * np.identity(3) self.basis = np.dot(self.directions, self.crystal_basis) self.check_basis_volume() def check_basis_volume(self): "Check the volume of the unit cell." vol1 = abs(np.linalg.det(self.basis)) cellsize = self.atoms_in_unit_cell if self.bravais_basis is not None: cellsize *= len(self.bravais_basis) vol2 = (self.calc_num_atoms() * self.latticeconstant**3 / cellsize) assert abs(vol1-vol2) < 1e-5 def find_directions(self, directions, miller): "Find missing directions and miller indices from the specified ones." directions = list(directions) miller = list(miller) # Process keyword "orthogonal" self.find_ortho(directions) self.find_ortho(miller) Bravais.find_directions(self, directions, miller) def find_ortho(self, idx): "Replace keyword 'ortho' or 'orthogonal' with a direction." for i in range(3): if isinstance(idx[i], str) and (idx[i].lower() == "ortho" or idx[i].lower() == "orthogonal"): if self.debug: print "Calculating orthogonal direction", i print idx[i-2], "X", idx[i-1], idx[i] = reduceindex(cross(idx[i-2], idx[i-1])) if self.debug: print "=", idx[i] SimpleCubic = SimpleCubicFactory() class FaceCenteredCubicFactory(SimpleCubicFactory): "A factory for creating face-centered cubic lattices." xtal_name = "fcc" int_basis = np.array([[0, 1, 1], [1, 0, 1], [1, 1, 0]]) basis_factor = 0.5 inverse_basis = np.array([[-1, 1, 1], [1, -1, 1], [1, 1, -1]]) inverse_basis_factor = 1.0 atoms_in_unit_cell = 4 FaceCenteredCubic = FaceCenteredCubicFactory() class BodyCenteredCubicFactory(SimpleCubicFactory): "A factory for creating body-centered cubic lattices." xtal_name = "bcc" int_basis = np.array([[-1, 1, 1], [1, -1, 1], [1, 1, -1]]) basis_factor = 0.5 inverse_basis = np.array([[0, 1, 1], [1, 0, 1], [1, 1, 0]]) inverse_basis_factor = 1.0 atoms_in_unit_cell = 2 BodyCenteredCubic = BodyCenteredCubicFactory() class DiamondFactory(FaceCenteredCubicFactory): "A factory for creating diamond lattices." xtal_name = "diamond" bravais_basis = [[0,0,0], [0.25, 0.25, 0.25]] Diamond = DiamondFactory()