/ase/embed.py - Annoter - QMX - Forge du Centre Blaise Pascal

root / ase / embed.py @ 10

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+import math
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+from ase import Atom, Atoms
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+from ase.data import covalent_radii, atomic_numbers
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+import numpy as np
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+class Embed(Atoms):
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+    #--- constructor of the Embed class ---
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+    def __init__(self, system=None, cluster=None, cell_cluster = "Auto"):
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+        super(Embed, self).__init__()
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+        # define the atom map
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+        self.atom_map_sys_cl = []
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+        self.atom_map_cl_sys = []
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+        self.linkatoms = []
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+        # cluster dimensions
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+        self.xyz_cl_min = None
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+        self.xyz_cl_max = None
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+        # set the search radius for link atoms
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+        self.d = 10
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+        # define the systems for calculations
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+        self.set_system(system)
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+        self.set_cluster(cluster)
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+        # set the cell of the system
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+        self.set_cell(system.get_cell())
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+        self.cell_cluster = cell_cluster
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+        return
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+    #--- set the cluster ---
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+    def set_cluster(self, atoms):
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+        import copy
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+        # set the min/max cluster dimensions
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+        self.xyz_cl_min = atoms[0].get_position()
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+        self.xyz_cl_max = atoms[0].get_position()
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+        for atom in atoms:
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+            # assign the label "Cluster (10)" in atom.TAG
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+            atom.set_tag(10)
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+            xyz=atom.get_position()
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+            for i in xrange(3):
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+                # set the min/max cluster dimensions
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+                if xyz[i] < self.xyz_cl_min[i]:
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+                    self.xyz_cl_min[i] = xyz[i]
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+                if xyz[i] > self.xyz_cl_max[i]:
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+                    self.xyz_cl_max[i] = xyz[i]
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+        # add self.d around min/max cluster dimensions
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+        self.xyz_cl_min -= [self.d, self.d, self.d]
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+        self.xyz_cl_max += [self.d, self.d, self.d]
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+        # set the cluster for low and high level calculation
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+        self.atoms_cluster = atoms
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+        return
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+    #--- set the system ---
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+    def set_system(self, atoms):
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+        self.atoms_system = atoms
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+        # assign the label "Cluster (10)" in atom.TAG
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+        for atom in atoms:
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+            atom.set_tag(0)
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+        # update search radius for link atoms
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+        dx = 0
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+        for atom in atoms:
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+            r = covalent_radii[atom.get_atomic_number()]
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+            if (r > dx):
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+                dx = r
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+        self.d = dx * 2.1
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+        return
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+    #--- return cluster ---
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+    def get_cluster(self):
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+        return self.atoms_cluster
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+    def get_system(self):
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+        return self.atoms_system
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+    #--- Embedding ---
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+    def embed(self):
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+        # is the cluster and the host system definied ?
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+        if self.atoms_cluster is None or self.atoms_system is None:
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+            return
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+        self.find_cluster()
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+        self.set_linkatoms()
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+        print "link atoms found: ", len(self.linkatoms)
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+        if self.cell_cluster == "System":
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+            self.atoms_cluster.set_cell(self.atoms_system.get_cell())
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+        elif self.cell_cluster == "Auto":
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+            positions = self.atoms_cluster.get_positions()
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+            #find the biggest dimensions of the cluster in x,y,z direction
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+            l = 0
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+            for idir in xrange(3):
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+                l = max(l, positions[:, idir].max() - positions[:, idir].min())
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+            # calculate the box parameters (cluster + min 5 Ang)
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+            l = (math.floor(l/2.5)+1)*2.5 + 5.0
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+            # build cell
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+            cell = np.zeros((3, 3),  float)
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+            # apply cell parameters
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+            for idir in xrange(3):
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+                cell[idir, idir] = l
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+            # set parameters to cluster
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+            self.atoms_cluster.set_cell(cell)
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+            # print information on the screen
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+            print "length of box surrounding the cluster: ",
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+            print l*10,
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+            print "pm"
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+        else:
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+            self.atoms_cluster.set_cell(self.cell_cluster)
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+    def find_cluster(self):
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+        # set tolerance
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+        d = 0.001
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+        #atoms
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+        xyzs_cl=[]
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+        for atom_cl in self.atoms_cluster:
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+            xyzs_cl.append(atom_cl.get_position())
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+        xyzs_sys=[]
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+        for atom_sys in self.atoms_system:
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+            xyzs_sys.append(atom_sys.get_position())
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+        self.atom_map_sys_cl = np.zeros(len(self.atoms_system), int)
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+        self.atom_map_cl_sys = np.zeros(len(self.atoms_cluster), int)
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+        # loop over cluster atoms atom_sys
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+        for iat_sys in xrange(len(self.atoms_system)):
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+            # get the coordinates of the system atom atom_sys
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+            xyz_sys = xyzs_sys[iat_sys]
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+            # bSysOnly: no identical atom has been found
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+            bSysOnly = True
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+            # loop over system atoms atom_cl
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+            for iat_cl in xrange(len(self.atoms_cluster)):
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+                # difference vector between both atoms
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+                xyz_diff = np.abs(xyzs_sys[iat_sys]-xyzs_cl[iat_cl])
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+                # identical atoms
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+                if xyz_diff[0] < d and xyz_diff[1] < d and xyz_diff[2] < d:
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+                    # set tag (CLUSTER+HOST: 10) to atom_sys
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+                    self.atoms_system[iat_sys].set_tag(10)
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+                    # map the atom in the atom list
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+                    self.atom_map_sys_cl[iat_sys] = iat_cl
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+                    self.atom_map_cl_sys[iat_cl] = iat_sys
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+                    # atom has been identified
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+                    bSysOnly = False
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+                    break
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+            if bSysOnly:
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+                self.atom_map_sys_cl[iat_sys] = -1
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+    def set_linkatoms(self, tol=15., linkAtom=None, debug=False):
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+        # local copies of xyz coordinates to avoid massive copying of xyz objects
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+        xyzs_cl=[]
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+        for atom_cl in self.atoms_cluster:
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+            xyzs_cl.append(atom_cl.get_position())
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+        xyzs_sys=[]
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+        for atom_sys in self.atoms_system:
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+            xyzs_sys.append(atom_sys.get_position())
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+        # set the standard link atom
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+        if linkAtom is None:
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+            linkAtom ='H'
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+        # number of atoms in the cluster and the system
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+        nat_cl=len(self.atoms_cluster)
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+        nat_sys=len(self.atoms_system)
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+        # system has pbc?
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+        pbc = self.get_pbc()
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+        # set the bond table
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+        bonds = []
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+        # set the 27 cell_vec, starting with the (0,0,0) vector for the unit cell
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+        cells_L = [(0.0,  0.0,  0.0)]
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+        # get the cell vectors of the host system and build up a 3 by 3 supercell to search for neighbors in the surrounding
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+        cell = self.atoms_system.get_cell()
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+        if self.atoms_system.get_pbc().any():
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+            for ix in xrange(-1, 2):
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+                for iy in xrange(-1, 2):
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+                    for iz in xrange(-1, 2):
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+                        if ix == 0 and iy == 0 and iz == 0:
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+                            continue
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+                        cells_L.append(np.dot([ix, iy, iz], cell))
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+        # save the radius of system atoms
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+        rs_sys = []
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+        for atom in self.atoms_system:
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+            rs_sys.append(covalent_radii[atom.get_atomic_number()])
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+        # sum over cluster atoms (iat_cl)
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+        for iat_cl in xrange(nat_cl):
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+            # get the cluster atom
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+            atom_cl=self.atoms_cluster[iat_cl]
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+            # ignore link atoms
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+            if atom_cl.get_tag() == 50:
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+                continue
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+            # xyz coordinates and covalent radius of the cluster atom iat_cl
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+            xyz_cl = xyzs_cl[iat_cl]
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+            r_cl = covalent_radii[atom_cl.get_atomic_number()]
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+            # sum over system atoms (iat_sys)
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+            for iat_sys in xrange(nat_sys):
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+                # avoid cluster atoms
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+                if self.atoms_system[iat_sys].get_tag()==10:
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+                    continue
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+                # sum over all cell_L
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+                for cell_L in cells_L:
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+                    # xyz coordinates and covalent radius of the system atom iat_sys
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+                    xyz_sys = xyzs_sys[iat_sys]+cell_L
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+                    # go only in distance self.d around the cluster
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+                    lcont = True
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+                    for i in xrange(3):
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+                        if (xyz_sys[i] < self.xyz_cl_min[i] or
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+                            xyz_sys[i] > self.xyz_cl_max[i]):
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+                            lcont = False
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+                            break
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+                    if not lcont:
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+                        continue
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+                    # xyz coordinates and covalent radius of the system atom iat_sys
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+                    r_sys = rs_sys[iat_sys]
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+                    # diff vector
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+                    xyz_diff = xyz_sys - xyz_cl
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+                    # distance between the atoms
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+                    r = np.sqrt(np.dot(xyz_diff, xyz_diff))
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+                    # ratio of the distance to the sum of covalent radius
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+                    f = r / (r_cl + r_sys)
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+                    if debug:
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+                        print "Covalent radii = ",r_cl, r_sys
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+                        print "Distance ", f
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+                        print "tol = ",(1+tol/100.),(1-tol/100.),(1-2*tol/100.)
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+                    if f <= (1+tol/100.) and f >= (1-2*tol/100.):
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+                        s = cell_L, self.atom_map_cl_sys[iat_cl], iat_sys, r_cl
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+                        bonds.append(s)
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+                        break
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+                    if f <= (1-2*tol/100.):
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+                        raise RuntimeError("QMX: The cluster atom", iat_cl, " and the system atom", iat_sys, "came too close")
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+        r_h = covalent_radii[atomic_numbers[linkAtom]]
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+        for bond in bonds:
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+            cell_L, iat_cl_sys, iat_sys, r_cl = bond
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+            # assign the tags for the border atoms
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+            atom_sys.set_tag(1)
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+            atom_cl.set_tag(11)
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+            #difference vector for the link atom, scaling
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+            xyz_diff = xyzs_sys[iat_sys] + cell_L - xyzs_sys[iat_cl_sys]
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+            r = (r_cl + r_h)
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+            xyz_diff *=  r / np.sqrt(np.dot(xyz_diff, xyz_diff))
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+            # determine position of the link atom
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+            xyz_diff += xyzs_sys[iat_cl_sys]
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+            # create link atom
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+            atom = Atom(symbol=linkAtom, position=xyz_diff, tag=50)
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+            # add atom to cluster
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+            self.atoms_cluster.append(atom)
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+            # add atom to the linkatoms
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+            s = cell_L, iat_cl_sys, iat_sys, r, len(self.atoms_cluster)-1
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+            self.linkatoms.append(s)
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+        return
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+    def set_positions(self, positions_new):
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+        # number of atoms
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+        nat_sys=len(self.atoms_system)
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+        # go over all pairs of atoms
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+        for iat_sys in xrange(nat_sys):
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+            xyz = positions_new[iat_sys]
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+            self.atoms_system[iat_sys].set_position(xyz)
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+            iat_cl = self.atom_map_sys_cl[iat_sys]
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+            if iat_cl > -1:
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+                self.atoms_cluster[iat_cl].set_position(xyz)
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+        for cell_L, iat_cl_sys, iat_sys, r, iat in self.linkatoms:
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+            # determine position of the link atom
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+            xyz_cl = positions_new[iat_cl_sys]
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+            xyz = positions_new[iat_sys] - xyz_cl + cell_L
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+            xyz *= r / np.sqrt(np.dot(xyz, xyz))
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+            xyz += xyz_cl
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+            # update xyz coordinates of the cluster
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+            self.atoms_cluster[iat].set_position(xyz)
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+    def __getitem__(self, i):
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+        return self.atoms_system.__getitem__(i)
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+    def get_positions(self):
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+        return self.atoms_system.get_positions()
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+    def __add__(self, other):
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+        return self.atoms_system.__add__(other)
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+    def __delitem__(self, i):
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+        return self.atoms_system.__delitem__(i)
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+    def __len__(self):
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+        return self.atoms_system.__len__()
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+    def get_chemical_symbols(self, reduce=False):
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+        return self.atoms_system.get_chemical_symbols(reduce)

Chimie Théorique » QMX

root / ase / embed.py @ 10