# Copyright (c) [2024-2025] [Grogupy Team]
#
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import copy
from typing import TYPE_CHECKING, Union
from numpy.typing import NDArray
if TYPE_CHECKING:
from .hamiltonian import Hamiltonian
import numpy as np
import sisl
from .. import __version__
from .._core.utilities import arrays_lists_equal, arrays_None_equal
from .utilities import (
blow_up_orbindx,
calculate_anisotropy_tensor,
fit_anisotropy_tensor,
interaction_energy,
parse_magnetic_entity,
second_order_energy,
)
[docs]
class MagneticEntity:
"""This class contains the data and the methods related to the magnetic entities.
It sets up the instance based on the indexing of the Hamiltonian by the ``atom``,
``l`` and orbital (``orb``) parameters.
There are four possible input types:
1. Cluster: a list of atoms
2. AtomShell: one atom and a list of shells indexed in the atom or
a list of atoms and a list of lists containing the shells
3. AtomOrbital: one atom and a list of orbitals indexed in the atom or
a list of atoms and a list of lists containing the orbitals
4. Orbitals: a list of orbitals indexed in the Hamiltonian
Parameters
----------
infile: Union[str, tuple[Union[sisl.physics.Hamiltonian, Hamiltonian], Union[sisl.physics.DensityMatrix, None]]]
Either the path to the .fdf file or a tuple of sisl or grogupy hamiltonian and a sisl density matrix
atom: Union[None, int, list[int]], optional
Defining atom (or atoms) in the unit cell forming the magnetic entity, by default None
l: Union[None, int, list[int], list[list[int]]], optional
Defining the angular momentum channel, by default None
orb: Union[None, int, list[int], list[list[int]]], optional
Defining the orbital index in the Hamiltonian or on the atom, by default None
Examples
--------
Creating a magnetic entity can be done by giving the Hamiltonian from the
DFT calculation and somehow specifying the corresponding atoms and orbitals.
The following examples show you how to create magnetic entities in the
**Fe3GeTe2** system. You can compare the tags of the ``MagneticEntity``
to the input parameters, to understand how to build the magnetic entity,
that suits your needs.
>>> fdf_path = "/Users/danielpozsar/Downloads/Fe3GeTe2/Fe3GeTe2.fdf"
To define a Cluster of atoms use a dictionary that only contains atoms.
>>> magnetic_entity = MagneticEntity(fdf_path, atom=[3,4,5])
>>> print(magnetic_entity.tag)
3Fe(l:All)--4Fe(l:All)--5Fe(l:All)
To define a magnetic entity with a single atom, but with specific
shells use both the ``atom`` and ``l`` key in the dictionary.
>>> magnetic_entity = MagneticEntity(fdf_path, atom=5, l=[[1,2,3]])
>>> print(magnetic_entity.tag)
5Fe(l:1-2-3)
Or you can define multiple atoms with different shells:
>>> magnetic_entity = MagneticEntity(fdf_path, atom=[4,5], l=[[1],[1,2,3]])
>>> print(magnetic_entity.tag)
4Fe(l:1)--5Fe(l:1-2-3)
To define a magnetic entity with a single atom, but with specific
orbitals use both the ``atom`` and ``orb`` key in the dictionary.
Be aware that these orbitals are indexed inside the atom, not in the
total Hamiltonian.
>>> magnetic_entity = MagneticEntity(fdf_path, atom=5, orb=[[1,2,3,4,5,6,7,8,9,10]])
>>> print(magnetic_entity.tag)
5Fe(o:1-2-3-4-5-6-7-8-9-10)
Or you can define multiple atoms with different orbitals:
>>> magnetic_entity = MagneticEntity(fdf_path, atom=[4,5], orb=[[1],[1,2,3,4,5,6,7,8,9,10]])
>>> print(magnetic_entity.tag)
4Fe(o:1)--5Fe(o:1-2-3-4-5-6-7-8-9-10)
And finally you can use only the ``orb`` key to directly index the
orbitals from the Hamiltonian.
>>> magnetic_entity = MagneticEntity(fdf_path, orb=[1,10,30,40,50])
>>> print(magnetic_entity.tag)
0Te(o:1-10)--2Ge(o:4)--3Fe(o:1-11)
Methods
-------
calculate_energies(weights) :
Calculates the energies of the infinitesimal rotations.
calculate_anisotropy() :
Calculates the anisotropy matrix and the consistency from the energies.
copy() :
Return a copy of this MagneticEntity
Attributes
----------
_orbital_box_indices : NDArray
The ORBITAL BOX indices
_atom : NDArray
The list of atoms in the magnetic entity
_l : list[list[Union[None, int]]]
The list of l in the magnetic entity, None if it is incomplete
_spin_box_indices : NDArray
The SPIN BOX indices
_total_mulliken: Union[None, NDArray]
Sisl Mulliken charges from the total atom
_local_mulliken: Union[None, NDArray]
Sisl Mulliken charges from the given orbitals
SBS : int
Length of the SPIN BOX indices
_xyz : NDArray
The coordinates of the magnetic entity (it can consist of many atoms)
_xyz_center : NDArray
The center of coordinates for the magnetic entity
_tag : str
The description of the magnetic entity
_Vu1 : list[list[float]]
The list of the first order rotations
_Vu2 : list[list[float]]
The list of the second order rotations
_Gii : list[NDArray]
The list of the projected Greens functions
energies : Union[None, NDArray]
The calculated energies for each direction
K : Union[NDArray, None]
The magnetic anisotropy, by default None
K_consistency : Union[float, None]
Consistency check on the diagonal K elements, by default None
"""
number_of_entities: int = 0
[docs]
def __init__(
self,
infile: Union[
str,
tuple[
Union[sisl.physics.Hamiltonian, "Hamiltonian"],
Union[sisl.physics.DensityMatrix, None],
],
],
atom: Union[None, int, list[int]] = None,
l: Union[None, int, list[int], list[list[int]]] = None,
orb: Union[None, int, list[int], list[list[int]]] = None,
) -> None:
"""Initialize the magnetic entity."""
if isinstance(infile, str):
# get sisl sile
sile = sisl.io.get_sile(infile)
# load density and hamiltonian
self._dh: sisl.physics.Hamiltonian = sile.read_hamiltonian()
try:
self._ds: sisl.physics.DensityMatrix = sile.read_density_matrix()
except:
self._ds = None
self.infile: str = infile
elif isinstance(infile, tuple):
self._dh: sisl.physics.Hamiltonian = infile[0]
self._ds: sisl.physics.DensityMatrix = infile[1]
self.infile: str = "Unknown!"
else:
raise Exception("Cannot setup without path or sisl objects!")
atom, l, orbital, tag = parse_magnetic_entity(self._dh, atom, l, orb)
self._atom: NDArray = np.array([atom]).flatten()
self._l = l
self._orbital_box_indices: NDArray = np.array(orbital).flatten()
self._tags = tag
# try to get Mulliken charges
if self._ds is not None:
self._total_mulliken: NDArray = self._ds.mulliken()[
:, self._dh.a2o(self._atom, all=True)
]
self._local_mulliken: NDArray = self._ds.mulliken()[
:, self._orbital_box_indices
]
else:
self._total_mulliken: None = None
self._local_mulliken: None = None
self._spin_box_indices: NDArray = blow_up_orbindx(self._orbital_box_indices)
self._xyz: NDArray = np.array([self._dh.xyz[i] for i in self._atom])
# initialize simulation parameters
self._Vu1: list[list[NDArray]] = []
self._Vu2: list[list[NDArray]] = []
self._Gii: list[NDArray] = []
self._Gii_tmp: list[NDArray] = []
self.energies: Union[list, NDArray] = None
self.K: Union[None, NDArray] = None
self.K_consistency: Union[None, float] = None
# pre calculate hidden unuseed properties
# they are here so they are dumped to the self.__dict__ upon saving
self.__tag = "--".join(self._tags)
self.__SBS = len(self._spin_box_indices)
self.__xyz_center = self._xyz.mean(axis=0)
# setup Mullikens if DM is available
if self._ds is not None:
self.__total_Q = self._total_mulliken[0].sum()
if self._total_mulliken.shape[0] == 2:
self.__total_Sx = 0
self.__total_Sy = 0
self.__total_Sz = self._total_mulliken[1].sum()
elif self._total_mulliken.shape[0] in {3, 4}:
self.__total_Sx = self._total_mulliken[1].sum()
self.__total_Sy = self._total_mulliken[2].sum()
self.__total_Sz = self._total_mulliken[3].sum()
else:
raise Exception("Unpolarized DFT calculation cannot be used!")
self.__local_Q = self._local_mulliken[0].sum()
if self._local_mulliken.shape[0] == 2:
self.__local_Sx = 0
self.__local_Sy = 0
self.__local_Sz = self._local_mulliken[1].sum()
elif self._local_mulliken.shape[0] in {3, 4}:
self.__local_Sx = self._local_mulliken[1].sum()
self.__local_Sy = self._local_mulliken[2].sum()
self.__local_Sz = self._local_mulliken[3].sum()
else:
raise Exception("Unpolarized DFT calculation cannot be used!")
else:
self.__total_Q = None
self.__total_Sx = None
self.__total_Sy = None
self.__total_Sz = None
self.__local_Q = None
self.__local_Sx = None
self.__local_Sy = None
self.__local_Sz = None
self.__energies_meV = None
self.__energies_mRy = None
self.__K_meV = None
self.__K_mRy = None
self.__K_consistency_meV = None
self.__K_consistency_mRy = None
MagneticEntity.number_of_entities += 1
def __getstate__(self):
return self.__dict__.copy()
def __setstate__(self, state):
self.__dict__ = state
def __add__(self, value):
if not isinstance(value, MagneticEntity):
raise Exception("Only MagneticEntity instances can be added!")
# do not change the current instance
new = self.copy()
# reset the values that does not make sense for a new magnetic entity
new.reset()
# update out instance
# accept both kinds of hamiltonian
if not arrays_lists_equal(new._dh.Hk().toarray(), value._dh.Hk().toarray()):
raise Exception("The sisl Hamiltonians are not the same!")
if not arrays_lists_equal(new._dh.Sk().toarray(), value._dh.Sk().toarray()):
raise Exception("The sisl Overlap matrices are not the same!")
new._atom = np.hstack((new._atom, value._atom))
new._l = new._l + value._l
new._orbital_box_indices = np.hstack(
(new._orbital_box_indices, value._orbital_box_indices)
)
new._tags = new._tags + value._tags
new._spin_box_indices = blow_up_orbindx(new._orbital_box_indices)
new._xyz = np.vstack((new._xyz, value._xyz))
return new
def __eq__(self, value):
if isinstance(value, MagneticEntity):
# if the IDs are identical, skip comaprison
if id(self) == id(value):
return True
# if there are sisl Hamiltonians, then compare
if self._dh is None and value._dh is None:
pass
else:
if not arrays_lists_equal(
self._dh.Hk().toarray(), value._dh.Hk().toarray()
):
return False
if not arrays_lists_equal(
self._dh.Sk().toarray(), value._dh.Sk().toarray()
):
return False
if not arrays_lists_equal(
self._ds.Dk().toarray(), value._ds.Dk().toarray()
):
return False
if not arrays_lists_equal(
self._ds.Sk().toarray(), value._ds.Sk().toarray()
):
return False
if not self.infile == value.infile:
return False
if not arrays_lists_equal(self._atom, value._atom):
return False
if not self._l == value._l:
return False
if not arrays_lists_equal(
self._orbital_box_indices, value._orbital_box_indices
):
return False
if not self._tags == value._tags:
return False
if not arrays_lists_equal(self._total_mulliken, value._total_mulliken):
return False
if not arrays_lists_equal(self._local_mulliken, value._local_mulliken):
return False
if not arrays_lists_equal(self._spin_box_indices, value._spin_box_indices):
return False
if not arrays_lists_equal(self._xyz, value._xyz):
return False
if not arrays_lists_equal(self._Vu1, value._Vu1):
return False
if not arrays_lists_equal(self._Vu2, value._Vu2):
return False
if not arrays_lists_equal(self._Gii, value._Gii):
return False
if not arrays_None_equal(self.energies, value.energies):
return False
if not arrays_None_equal(self.K, value.K):
return False
# Checking K_consistency separately
# if both are None, then pass and no other check is perfomred because of elif
if self.K_consistency is None and value.K_consistency is None:
pass
# if either one is None, but the other is not, then return false
elif self.K_consistency is not None and value.K_consistency is None:
return False
elif self.K_consistency is None and value.K_consistency is not None:
return False
# If neither of them is None, compare them
elif not np.isclose(self.K_consistency, value.K_consistency):
return False
return True
else:
return False
def __repr__(self) -> str:
"""String representation of the instance."""
out = f"<grogupy.MagneticEntity tag={self.tag}, SBS={self.SBS}>"
return out
@property
def tag(self):
"""The description of the magnetic entity"""
self.__tag = "--".join(self._tags)
return self.__tag
@property
def SBS(self) -> int:
"""The spin box size of the magnetic entity"""
self.__SBS = len(self._spin_box_indices)
return self.__SBS
@property
def xyz_center(self) -> NDArray:
"""The mean of the position of the atoms that are in the magnetic entity."""
self.__xyz_center = self._xyz.mean(axis=0)
return self.__xyz_center
@property
def total_Q(self) -> Union[NDArray, None]:
"""The total charge of the atom or the atoms of magnetic entity."""
# check if DM is available
if self._total_mulliken is None:
return None
self.__total_Q = self._total_mulliken[0].sum()
return self.__total_Q
@property
def total_Sx(self) -> Union[NDArray, None]:
"""Sx of the atom or the atoms of the magnetic entity."""
# check if DM is available
if self._total_mulliken is None:
return None
if self._total_mulliken.shape[0] == 2:
self.__total_Sx = 0
elif self._total_mulliken.shape[0] in {3, 4}:
self.__total_Sx = self._total_mulliken[1].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__total_Sx
@property
def total_Sy(self) -> Union[NDArray, None]:
"""Sy of the atom or the atoms of the magnetic entity."""
# check if DM is available
if self._total_mulliken is None:
return None
if self._total_mulliken.shape[0] == 2:
self.__total_Sy = 0
elif self._total_mulliken.shape[0] in {3, 4}:
self.__total_Sy = self._total_mulliken[2].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__total_Sy
@property
def total_Sz(self) -> Union[NDArray, None]:
"""Sz of the atom or the atoms of the magnetic entity."""
# check if DM is available
if self._total_mulliken is None:
return None
if self._total_mulliken.shape[0] == 2:
self.__total_Sz = self._total_mulliken[1].sum()
elif self._total_mulliken.shape[0] in {3, 4}:
self.__total_Sz = self._total_mulliken[3].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__total_Sz
@property
def local_Q(self) -> Union[NDArray, None]:
"""The charge of the magnetic entity."""
# check if DM is available
if self._local_mulliken is None:
return None
self.__local_Q = self._local_mulliken[0].sum()
return self.__local_Q
@property
def local_Sx(self) -> Union[NDArray, None]:
"""Sx of the magnetic entity."""
# check if DM is available
if self._local_mulliken is None:
return None
if self._local_mulliken.shape[0] == 2:
self.__local_Sx = 0
elif self._local_mulliken.shape[0] in {3, 4}:
self.__local_Sx = self._local_mulliken[1].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__local_Sx
@property
def local_Sy(self) -> Union[NDArray, None]:
"""Sy of the magnetic entity."""
# check if DM is available
if self._local_mulliken is None:
return None
if self._local_mulliken.shape[0] == 2:
self.__local_Sy = 0
elif self._local_mulliken.shape[0] in {3, 4}:
self.__local_Sy = self._local_mulliken[2].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__local_Sy
@property
def local_Sz(self) -> Union[NDArray, None]:
"""Sz of the magnetic entity."""
# check if DM is available
if self._local_mulliken is None:
return None
if self._local_mulliken.shape[0] == 2:
self.__local_Sz = self._local_mulliken[1].sum()
elif self._local_mulliken.shape[0] in {3, 4}:
self.__local_Sz = self._local_mulliken[3].sum()
else:
Exception("Unpolarized DFT calculation cannot be used!")
return self.__local_Sz
@property
def energies_meV(self) -> NDArray:
"""The energies, but in meV."""
if self.energies is None:
self.__energies_meV = None
else:
self.__energies_meV = self.energies * sisl.unit_convert("eV", "meV")
return self.__energies_meV
@property
def energies_mRy(self) -> NDArray:
"""The energies, but in mRy."""
if self.energies is None:
self.__energies_mRy = None
else:
self.__energies_mRy = self.energies * sisl.unit_convert("eV", "mRy")
return self.__energies_mRy
@property
def K_meV(self) -> NDArray:
"""The anisotropy tensor, but in meV."""
if self.K is None:
self.__K_meV = None
else:
self.__K_meV = self.K * sisl.unit_convert("eV", "meV")
return self.__K_meV
@property
def K_mRy(self) -> NDArray:
"""The anisotropy tensor, but in mRy."""
if self.K is None:
self.__K_mRy = None
else:
self.__K_mRy = self.K * sisl.unit_convert("eV", "mRy")
return self.__K_mRy
@property
def K_consistency_meV(self) -> NDArray:
"""The consistency check, but in meV."""
if self.K_consistency is None:
self.__K_consistency_meV = None
else:
self.__K_consistency_meV = self.K_consistency * sisl.unit_convert(
"eV", "meV"
)
return self.__K_consistency_meV
@property
def K_consistency_mRy(self) -> NDArray:
"""The consistency check, but in mRy."""
if self.K_consistency is None:
self.__K_consistency_mRy = None
else:
self.__K_consistency_mRy = self.K_consistency * sisl.unit_convert(
"eV", "mRy"
)
return self.__K_consistency_mRy
def reset(self) -> None:
"""Resets the simulation results."""
self._Vu1: list[list[NDArray]] = []
self._Vu2: list[list[NDArray]] = []
self._Gii: list[NDArray] = []
self._Gii_tmp: list[NDArray] = []
self.energies: list[NDArray] = None
self.K: Union[None, NDArray] = None
self.K_consistency: Union[None, float] = None
def calculate_energies(self, weights: NDArray, matlabmode: bool = False) -> None:
"""Calculates the energies of the infinitesimal rotations.
It uses the instance properties to calculate the energies and
dumps the results to the ``energies`` property.
Parameters
----------
weights : NDArray
The weights of the energy contour integral
matlabmode : bool, optional
Wether to use a linear combination of the two perpendicular
orientation, by default False
"""
energies: list[list[float]] = []
for i, Gii in enumerate(self._Gii):
storage: list[float] = []
# iterate over the first and second order local perturbations
V1 = self._Vu1[i]
V2 = self._Vu2[i]
# fill up the magnetic entities dictionary with the energies
storage.append(second_order_energy(V1[0], V2[0], Gii, weights))
storage.append(interaction_energy(V1[0], V1[1], Gii, Gii, weights))
storage.append(interaction_energy(V1[1], V1[0], Gii, Gii, weights))
storage.append(second_order_energy(V1[1], V2[1], Gii, weights))
if matlabmode:
storage.append(second_order_energy(V1[2], V2[2], Gii, weights))
energies.append(storage)
# convert to array
self.energies: NDArray = np.array(energies)
# call these so they are updated
self.energies_meV
self.energies_mRy
def calculate_anisotropy(self) -> None:
"""Calculates the anisotropy matrix and the consistency from the energies.
It uses the instance properties to calculate the anisotropy matrix and the
consistency and dumps them to the `K`, `K_consistency` properties.
"""
K, K_consistency = calculate_anisotropy_tensor(self.energies)
self.K: NDArray = K
self.K_consistency: float = K_consistency
# call these so they are updated
self.K_meV
self.K_mRy
self.K_consistency_meV
self.K_consistency_mRy
def fit_anisotropy_tensor(self, ref_xcf: list[dict]) -> None:
"""Fits the anisotropy tensor to the energies.
It uses a fitting method to calculate the anisotropy tensor from the
reference directions and its different representations and dumps
them to the ``K`` property. It writes ``None`` to the ``K_consistency``
property.
Parameters
----------
ref_xcf: list[dict]
The reference directions containing the orientation and perpendicular directions
"""
K = fit_anisotropy_tensor(self.energies, ref_xcf)
self.K: NDArray = K
# it is not relevant with this method
self.K_consistency: Union[float, None] = None
# call these so they are updated
self.K_meV
self.K_mRy
self.K_consistency_meV
self.K_consistency_mRy
def copy(self):
"""Returns the deepcopy of the instance.
Returns
-------
MagneticEntity
The copied instance.
"""
return copy.deepcopy(self)
if __name__ == "__main__":
pass