root / ase / lattice / surface.py @ 5
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| 1 | 1 | tkerber | """Helper functions for creating the most common surfaces and related tasks.
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| 2 | 1 | tkerber |
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| 3 | 1 | tkerber | The helper functions can create the most common low-index surfaces,
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| 4 | 1 | tkerber | add vacuum layers and add adsorbates.
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| 5 | 1 | tkerber |
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| 6 | 1 | tkerber | """
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| 7 | 1 | tkerber | |
| 8 | 1 | tkerber | from math import sqrt |
| 9 | 1 | tkerber | |
| 10 | 1 | tkerber | import numpy as np |
| 11 | 1 | tkerber | |
| 12 | 1 | tkerber | from ase.atom import Atom |
| 13 | 1 | tkerber | from ase.atoms import Atoms |
| 14 | 1 | tkerber | from ase.data import reference_states, atomic_numbers |
| 15 | 1 | tkerber | |
| 16 | 1 | tkerber | |
| 17 | 1 | tkerber | def fcc100(symbol, size, a=None, vacuum=None): |
| 18 | 1 | tkerber | """FCC(100) surface.
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| 19 | 1 | tkerber |
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| 20 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'bridge', 'hollow'."""
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| 21 | 1 | tkerber | return surface(symbol, 'fcc', '100', size, a, None, vacuum) |
| 22 | 1 | tkerber | |
| 23 | 1 | tkerber | def fcc110(symbol, size, a=None, vacuum=None): |
| 24 | 1 | tkerber | """FCC(110) surface.
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| 25 | 1 | tkerber |
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| 26 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'longbridge',
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| 27 | 1 | tkerber | 'shortbridge','hollow'."""
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| 28 | 1 | tkerber | return surface(symbol, 'fcc', '110', size, a, None, vacuum) |
| 29 | 1 | tkerber | |
| 30 | 1 | tkerber | def bcc100(symbol, size, a=None, vacuum=None): |
| 31 | 1 | tkerber | """BCC(100) surface.
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| 32 | 1 | tkerber |
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| 33 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'bridge', 'hollow'."""
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| 34 | 1 | tkerber | return surface(symbol, 'bcc', '100', size, a, None, vacuum) |
| 35 | 1 | tkerber | |
| 36 | 1 | tkerber | def bcc110(symbol, size, a=None, vacuum=None, orthogonal=False): |
| 37 | 1 | tkerber | """BCC(110) surface.
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| 38 | 1 | tkerber |
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| 39 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'longbridge',
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| 40 | 1 | tkerber | 'shortbridge', 'hollow'.
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| 41 | 1 | tkerber |
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| 42 | 1 | tkerber | Use *orthogonal=True* to get an orthogonal unit cell - works only
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| 43 | 1 | tkerber | for size=(i,j,k) with j even."""
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| 44 | 1 | tkerber | return surface(symbol, 'bcc', '110', size, a, None, vacuum, orthogonal) |
| 45 | 1 | tkerber | |
| 46 | 1 | tkerber | def bcc111(symbol, size, a=None, vacuum=None, orthogonal=False): |
| 47 | 1 | tkerber | """BCC(111) surface.
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| 48 | 1 | tkerber |
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| 49 | 1 | tkerber | Supported special adsorption sites: 'ontop'.
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| 50 | 1 | tkerber |
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| 51 | 1 | tkerber | Use *orthogonal=True* to get an orthogonal unit cell - works only
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| 52 | 1 | tkerber | for size=(i,j,k) with j even."""
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| 53 | 1 | tkerber | return surface(symbol, 'bcc', '111', size, a, None, vacuum, orthogonal) |
| 54 | 1 | tkerber | |
| 55 | 1 | tkerber | def fcc111(symbol, size, a=None, vacuum=None, orthogonal=False): |
| 56 | 1 | tkerber | """FCC(111) surface.
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| 57 | 1 | tkerber |
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| 58 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'bridge', 'fcc' and 'hcp'.
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| 59 | 1 | tkerber |
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| 60 | 1 | tkerber | Use *orthogonal=True* to get an orthogonal unit cell - works only
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| 61 | 1 | tkerber | for size=(i,j,k) with j even."""
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| 62 | 1 | tkerber | return surface(symbol, 'fcc', '111', size, a, None, vacuum, orthogonal) |
| 63 | 1 | tkerber | |
| 64 | 1 | tkerber | def hcp0001(symbol, size, a=None, c=None, vacuum=None, orthogonal=False): |
| 65 | 1 | tkerber | """HCP(0001) surface.
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| 66 | 1 | tkerber |
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| 67 | 1 | tkerber | Supported special adsorption sites: 'ontop', 'bridge', 'fcc' and 'hcp'.
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| 68 | 1 | tkerber |
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| 69 | 1 | tkerber | Use *orthogonal=True* to get an orthogonal unit cell - works only
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| 70 | 1 | tkerber | for size=(i,j,k) with j even."""
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| 71 | 1 | tkerber | return surface(symbol, 'hcp', '0001', size, a, c, vacuum, orthogonal) |
| 72 | 1 | tkerber | |
| 73 | 1 | tkerber | |
| 74 | 1 | tkerber | def add_adsorbate(slab, adsorbate, height, position=(0, 0), offset=None, |
| 75 | 1 | tkerber | mol_index=0):
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| 76 | 1 | tkerber | """Add an adsorbate to a surface.
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| 77 | 1 | tkerber |
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| 78 | 1 | tkerber | This function adds an adsorbate to a slab. If the slab is
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| 79 | 1 | tkerber | produced by one of the utility functions in ase.lattice.surface, it
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| 80 | 1 | tkerber | is possible to specify the position of the adsorbate by a keyword
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| 81 | 1 | tkerber | (the supported keywords depend on which function was used to
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| 82 | 1 | tkerber | create the slab).
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| 83 | 1 | tkerber |
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| 84 | 1 | tkerber | If the adsorbate is a molecule, the atom indexed by the mol_index
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| 85 | 1 | tkerber | optional argument is positioned on top of the adsorption position
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| 86 | 1 | tkerber | on the surface, and it is the responsibility of the user to orient
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| 87 | 1 | tkerber | the adsorbate in a sensible way.
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| 88 | 1 | tkerber |
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| 89 | 1 | tkerber | This function can be called multiple times to add more than one
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| 90 | 1 | tkerber | adsorbate.
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| 91 | 1 | tkerber |
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| 92 | 1 | tkerber | Parameters:
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| 93 | 1 | tkerber |
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| 94 | 1 | tkerber | slab: The surface onto which the adsorbate should be added.
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| 95 | 1 | tkerber |
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| 96 | 1 | tkerber | adsorbate: The adsorbate. Must be one of the following three types:
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| 97 | 1 | tkerber | A string containing the chemical symbol for a single atom.
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| 98 | 1 | tkerber | An atom object.
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| 99 | 1 | tkerber | An atoms object (for a molecular adsorbate).
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| 100 | 1 | tkerber |
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| 101 | 1 | tkerber | height: Height above the surface.
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| 102 | 1 | tkerber |
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| 103 | 1 | tkerber | position: The x-y position of the adsorbate, either as a tuple of
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| 104 | 1 | tkerber | two numbers or as a keyword (if the surface is produced by one
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| 105 | 1 | tkerber | of the functions in ase.lattice.surfaces).
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| 106 | 1 | tkerber |
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| 107 | 1 | tkerber | offset (default: None): Offsets the adsorbate by a number of unit
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| 108 | 1 | tkerber | cells. Mostly useful when adding more than one adsorbate.
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| 109 | 1 | tkerber |
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| 110 | 1 | tkerber | mol_index (default: 0): If the adsorbate is a molecule, index of
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| 111 | 1 | tkerber | the atom to be positioned above the location specified by the
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| 112 | 1 | tkerber | position argument.
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| 113 | 1 | tkerber |
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| 114 | 1 | tkerber | Note *position* is given in absolute xy coordinates (or as
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| 115 | 1 | tkerber | a keyword), whereas offset is specified in unit cells. This
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| 116 | 1 | tkerber | can be used to give the positions in units of the unit cell by
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| 117 | 1 | tkerber | using *offset* instead.
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| 118 | 1 | tkerber |
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| 119 | 1 | tkerber | """
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| 120 | 1 | tkerber | info = slab.adsorbate_info |
| 121 | 1 | tkerber | if 'cell' not in info: |
| 122 | 1 | tkerber | info['cell'] = slab.get_cell()[:2,:2] |
| 123 | 1 | tkerber | |
| 124 | 1 | tkerber | |
| 125 | 1 | tkerber | pos = np.array([0.0, 0.0]) # (x, y) part |
| 126 | 1 | tkerber | spos = np.array([0.0, 0.0]) # part relative to unit cell |
| 127 | 1 | tkerber | if offset is not None: |
| 128 | 1 | tkerber | spos += np.asarray(offset, float)
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| 129 | 1 | tkerber | |
| 130 | 1 | tkerber | if isinstance(position, str): |
| 131 | 1 | tkerber | # A site-name:
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| 132 | 1 | tkerber | if 'sites' not in info: |
| 133 | 1 | tkerber | raise TypeError('If the atoms are not made by an ' + |
| 134 | 1 | tkerber | 'ase.lattice.surface function, ' +
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| 135 | 1 | tkerber | 'position cannot be a name.')
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| 136 | 1 | tkerber | if position not in info['sites']: |
| 137 | 1 | tkerber | raise TypeError('Adsorption site %s not supported.' % position) |
| 138 | 1 | tkerber | spos += info['sites'][position]
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| 139 | 1 | tkerber | else:
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| 140 | 1 | tkerber | pos += position |
| 141 | 1 | tkerber | |
| 142 | 1 | tkerber | pos += np.dot(spos, info['cell'])
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| 143 | 1 | tkerber | |
| 144 | 1 | tkerber | # Convert the adsorbate to an Atoms object
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| 145 | 1 | tkerber | if isinstance(adsorbate, Atoms): |
| 146 | 1 | tkerber | ads = adsorbate |
| 147 | 1 | tkerber | elif isinstance(adsorbate, Atom): |
| 148 | 1 | tkerber | ads = Atoms([adsorbate]) |
| 149 | 1 | tkerber | else:
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| 150 | 1 | tkerber | # Hope it is a useful string or something like that
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| 151 | 1 | tkerber | ads = Atoms(adsorbate) |
| 152 | 1 | tkerber | |
| 153 | 1 | tkerber | # Get the z-coordinate:
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| 154 | 1 | tkerber | try:
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| 155 | 1 | tkerber | a = info['top layer atom index']
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| 156 | 1 | tkerber | except KeyError: |
| 157 | 1 | tkerber | a = slab.positions[:, 2].argmax()
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| 158 | 1 | tkerber | info['top layer atom index']= a
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| 159 | 1 | tkerber | z = slab.positions[a, 2] + height
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| 160 | 1 | tkerber | |
| 161 | 1 | tkerber | # Move adsorbate into position
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| 162 | 1 | tkerber | ads.translate([pos[0], pos[1], z] - ads.positions[mol_index]) |
| 163 | 1 | tkerber | |
| 164 | 1 | tkerber | # Attach the adsorbate
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| 165 | 1 | tkerber | slab.extend(ads) |
| 166 | 1 | tkerber | |
| 167 | 1 | tkerber | |
| 168 | 1 | tkerber | def surface(symbol, structure, face, size, a, c, vacuum, orthogonal=True): |
| 169 | 1 | tkerber | """Function to build often used surfaces.
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| 170 | 1 | tkerber |
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| 171 | 1 | tkerber | Don't call this function directly - use fcc100, fcc110, bcc111, ..."""
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| 172 | 1 | tkerber | |
| 173 | 1 | tkerber | Z = atomic_numbers[symbol] |
| 174 | 1 | tkerber | |
| 175 | 1 | tkerber | if a is None: |
| 176 | 1 | tkerber | sym = reference_states[Z]['symmetry'].lower()
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| 177 | 1 | tkerber | if sym != structure:
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| 178 | 1 | tkerber | raise ValueError("Can't guess lattice constant for %s-%s!" % |
| 179 | 1 | tkerber | (structure, symbol)) |
| 180 | 1 | tkerber | a = reference_states[Z]['a']
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| 181 | 1 | tkerber | |
| 182 | 1 | tkerber | if structure == 'hcp' and c is None: |
| 183 | 1 | tkerber | if reference_states[Z]['symmetry'].lower() == 'hcp': |
| 184 | 1 | tkerber | c = reference_states[Z]['c/a'] * a
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| 185 | 1 | tkerber | else:
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| 186 | 1 | tkerber | c = sqrt(8 / 3.0) * a |
| 187 | 1 | tkerber | |
| 188 | 1 | tkerber | positions = np.empty((size[2], size[1], size[0], 3)) |
| 189 | 1 | tkerber | positions[..., 0] = np.arange(size[0]).reshape((1, 1, -1)) |
| 190 | 1 | tkerber | positions[..., 1] = np.arange(size[1]).reshape((1, -1, 1)) |
| 191 | 1 | tkerber | positions[..., 2] = np.arange(size[2]).reshape((-1, 1, 1)) |
| 192 | 1 | tkerber | |
| 193 | 1 | tkerber | numbers = np.ones(size[0] * size[1] * size[2], int) * Z |
| 194 | 1 | tkerber | |
| 195 | 1 | tkerber | tags = np.empty((size[2], size[1], size[0]), int) |
| 196 | 1 | tkerber | tags[:] = np.arange(size[2], 0, -1).reshape((-1, 1, 1)) |
| 197 | 1 | tkerber | |
| 198 | 1 | tkerber | slab = Atoms(numbers, |
| 199 | 1 | tkerber | tags=tags.ravel(), |
| 200 | 1 | tkerber | pbc=(True, True, False), |
| 201 | 1 | tkerber | cell=size) |
| 202 | 1 | tkerber | |
| 203 | 1 | tkerber | surface_cell = None
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| 204 | 1 | tkerber | sites = {'ontop': (0, 0)}
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| 205 | 1 | tkerber | surf = structure + face |
| 206 | 1 | tkerber | if surf == 'fcc100': |
| 207 | 1 | tkerber | cell = (sqrt(0.5), sqrt(0.5), 0.5) |
| 208 | 1 | tkerber | positions[-2::-2, ..., :2] += 0.5 |
| 209 | 1 | tkerber | sites.update({'hollow': (0.5, 0.5), 'bridge': (0.5, 0)})
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| 210 | 1 | tkerber | elif surf == 'fcc110': |
| 211 | 1 | tkerber | cell = (1.0, sqrt(0.5), sqrt(0.125)) |
| 212 | 1 | tkerber | positions[-2::-2, ..., :2] += 0.5 |
| 213 | 1 | tkerber | sites.update({'hollow': (0.5, 0.5), 'longbridge': (0.5, 0),
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| 214 | 1 | tkerber | 'shortbridge': (0, 0.5)}) |
| 215 | 1 | tkerber | elif surf == 'bcc100': |
| 216 | 1 | tkerber | cell = (1.0, 1.0, 0.5) |
| 217 | 1 | tkerber | positions[-2::-2, ..., :2] += 0.5 |
| 218 | 1 | tkerber | sites.update({'hollow': (0.5, 0.5), 'bridge': (0.5, 0)})
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| 219 | 1 | tkerber | else:
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| 220 | 1 | tkerber | if orthogonal and size[1] % 2 == 1: |
| 221 | 1 | tkerber | raise ValueError(("Can't make orthorhombic cell with size=%r. " % |
| 222 | 1 | tkerber | (tuple(size),)) +
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| 223 | 1 | tkerber | 'Second number in size must be even.')
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| 224 | 1 | tkerber | if surf == 'fcc111': |
| 225 | 1 | tkerber | cell = (sqrt(0.5), sqrt(0.375), 1 / sqrt(3)) |
| 226 | 1 | tkerber | if orthogonal:
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| 227 | 1 | tkerber | positions[-1::-3, 1::2, :, 0] += 0.5 |
| 228 | 1 | tkerber | positions[-2::-3, 1::2, :, 0] += 0.5 |
| 229 | 1 | tkerber | positions[-3::-3, 1::2, :, 0] -= 0.5 |
| 230 | 1 | tkerber | positions[-2::-3, ..., :2] += (0.0, 2.0 / 3) |
| 231 | 1 | tkerber | positions[-3::-3, ..., :2] += (0.5, 1.0 / 3) |
| 232 | 1 | tkerber | else:
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| 233 | 1 | tkerber | positions[-2::-3, ..., :2] += (-1.0 / 3, 2.0 / 3) |
| 234 | 1 | tkerber | positions[-3::-3, ..., :2] += (1.0 / 3, 1.0 / 3) |
| 235 | 1 | tkerber | sites.update({'bridge': (0.5, 0), 'fcc': (1.0 / 3, 1.0 / 3),
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| 236 | 1 | tkerber | 'hcp': (2.0 / 3, 2.0 / 3)}) |
| 237 | 1 | tkerber | elif surf == 'hcp0001': |
| 238 | 1 | tkerber | cell = (1.0, sqrt(0.75), 0.5 * c / a) |
| 239 | 1 | tkerber | if orthogonal:
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| 240 | 1 | tkerber | positions[:, 1::2, :, 0] += 0.5 |
| 241 | 1 | tkerber | positions[-2::-2, ..., :2] += (0.0, 2.0 / 3) |
| 242 | 1 | tkerber | else:
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| 243 | 1 | tkerber | positions[-2::-2, ..., :2] += (-1.0 / 3, 2.0 / 3) |
| 244 | 1 | tkerber | sites.update({'bridge': (0.5, 0), 'fcc': (1.0 / 3, 1.0 / 3),
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| 245 | 1 | tkerber | 'hcp': (2.0 / 3, 2.0 / 3)}) |
| 246 | 1 | tkerber | elif surf == 'bcc110': |
| 247 | 1 | tkerber | cell = (1.0, sqrt(0.5), sqrt(0.5)) |
| 248 | 1 | tkerber | if orthogonal:
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| 249 | 1 | tkerber | positions[:, 1::2, :, 0] += 0.5 |
| 250 | 1 | tkerber | positions[-2::-2, ..., :2] += (0.0, 1.0) |
| 251 | 1 | tkerber | else:
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| 252 | 1 | tkerber | positions[-2::-2, ..., :2] += (-0.5, 1.0) |
| 253 | 1 | tkerber | sites.update({'shortbridge': (0, 0.5),
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| 254 | 1 | tkerber | 'longbridge': (0.5, 0), |
| 255 | 1 | tkerber | 'hollow': (0.375, 0.25)}) |
| 256 | 1 | tkerber | elif surf == 'bcc111': |
| 257 | 1 | tkerber | cell = (sqrt(2), sqrt(1.5), sqrt(3) / 6) |
| 258 | 1 | tkerber | if orthogonal:
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| 259 | 1 | tkerber | positions[-1::-3, 1::2, :, 0] += 0.5 |
| 260 | 1 | tkerber | positions[-2::-3, 1::2, :, 0] += 0.5 |
| 261 | 1 | tkerber | positions[-3::-3, 1::2, :, 0] -= 0.5 |
| 262 | 1 | tkerber | positions[-2::-3, ..., :2] += (0.0, 2.0 / 3) |
| 263 | 1 | tkerber | positions[-3::-3, ..., :2] += (0.5, 1.0 / 3) |
| 264 | 1 | tkerber | else:
|
| 265 | 1 | tkerber | positions[-2::-3, ..., :2] += (-1.0 / 3, 2.0 / 3) |
| 266 | 1 | tkerber | positions[-3::-3, ..., :2] += (1.0 / 3, 1.0 / 3) |
| 267 | 1 | tkerber | sites.update({'hollow': (1.0 / 3, 1.0 / 3)})
|
| 268 | 1 | tkerber | |
| 269 | 1 | tkerber | surface_cell = a * np.array([(cell[0], 0), |
| 270 | 1 | tkerber | (cell[0] / 2, cell[1])]) |
| 271 | 1 | tkerber | if not orthogonal: |
| 272 | 1 | tkerber | cell = np.array([(cell[0], 0, 0), |
| 273 | 1 | tkerber | (cell[0] / 2, cell[1], 0), |
| 274 | 1 | tkerber | (0, 0, cell[2])]) |
| 275 | 1 | tkerber | |
| 276 | 1 | tkerber | if surface_cell is None: |
| 277 | 1 | tkerber | surface_cell = a * np.diag(cell[:2])
|
| 278 | 1 | tkerber | |
| 279 | 1 | tkerber | if isinstance(cell, tuple): |
| 280 | 1 | tkerber | cell = np.diag(cell) |
| 281 | 1 | tkerber | |
| 282 | 1 | tkerber | slab.set_positions(positions.reshape((-1, 3))) |
| 283 | 1 | tkerber | |
| 284 | 1 | tkerber | slab.set_cell([a * v * n for v, n in zip(cell, size)], scale_atoms=True) |
| 285 | 1 | tkerber | |
| 286 | 1 | tkerber | if vacuum is not None: |
| 287 | 1 | tkerber | slab.center(vacuum=vacuum, axis=2)
|
| 288 | 1 | tkerber | |
| 289 | 1 | tkerber | slab.adsorbate_info['cell'] = surface_cell
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| 290 | 1 | tkerber | slab.adsorbate_info['sites'] = sites
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| 291 | 1 | tkerber | |
| 292 | 1 | tkerber | return slab
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| 293 | 1 | tkerber | |
| 294 | 1 | tkerber |