def dia(self, mol=None, dm0=None, gauge_orig=None, shielding_nuc=None): if mol is None: mol = self.mol if dm0 is None: dm0 = self._scf.make_rdm1() if not (isinstance(dm0, numpy.ndarray) and dm0.ndim == 2): # spin-traced 1pdm dm0 = dm0[0] + dm0[1] return rhf_nmr.dia(mol, dm0, gauge_orig, shielding_nuc)
def dia(nsrobj, gauge_orig=None, shielding_nuc=None, dm0=None): '''Diamagnetic part of NSR tensors. ''' if shielding_nuc is None: shielding_nuc = nsrobj.shielding_nuc if dm0 is None: dm0 = nsrobj._scf.make_rdm1() mol = nsrobj.mol im, mass_center = inertia_tensor(mol) if gauge_orig is None: ao_coords = rhf_mag._get_ao_coords(mol) # Eq. (34) of JCP, 105, 2804 nsr_dia = rhf_nmr.dia(nsrobj, gauge_orig, shielding_nuc, dm0) for n, atm_id in enumerate(shielding_nuc): coord = mol.atom_coord(atm_id) with mol.with_common_origin(coord): with mol.with_rinv_origin(coord): # a11part = (B dot) -1/2 frac{\vec{r}_N}{r_N^3} r_N (dot mu) h11 = mol.intor('int1e_cg_a11part', comp=9) e11 = numpy.einsum('xpq,qp->x', h11, dm0).reshape(3, 3) nsr_dia[n] -= e11 - numpy.eye(3) * e11.trace() nsr_dia[n] *= 2 else: nsr_dia = [] for n, atm_id in enumerate(shielding_nuc): coord = mol.atom_coord(atm_id) with mol.with_rinv_origin(coord): with mol.with_common_origin(gauge_orig): # a11part = (B dot) -1/2 frac{\vec{r}_N}{r_N^3} (r-R_c) (dot mu) h11 = mol.intor('int1e_cg_a11part', comp=9) e11 = numpy.einsum('xpq,qp->x', h11, dm0).reshape(3, 3) with mol.with_common_origin(coord): # a11part = (B dot) -1/2 frac{\vec{r}_N}{r_N^3} r_N (dot mu) h11 = mol.intor('int1e_cg_a11part', comp=9) # e11 ~ (B dot) -1/2 frac{\vec{r}_N}{r_N^3} (R_N-R_c) (dot mu) e11 -= numpy.einsum('xpq,qp->x', h11, dm0).reshape(3, 3) e11 = e11 - numpy.eye(3) * e11.trace() nsr_dia.append(e11) nsr_dia = _safe_solve(im, numpy.asarray(nsr_dia)) unit = _atom_gyro_list(mol)[shielding_nuc] * nist.ALPHA**2 return numpy.einsum('ixy,i->ixy', nsr_dia, unit)
def dia(nmrobj, gauge_orig=None, shielding_nuc=None, dm0=None): if dm0 is None: dm0 = nmrobj._scf.make_rdm1() if not (isinstance(dm0, numpy.ndarray) and dm0.ndim == 2): dm0 = dm0[0] + dm0[1] return rhf_nmr.dia(nmrobj, gauge_orig, shielding_nuc, dm0)
def dia(mol, dm0, gauge_orig=None, shielding_nuc=None): if not (isinstance(dm0, numpy.ndarray) and dm0.ndim == 2): dm0 = dm0[0] + dm0[1] return rhf_nmr.dia(mol, dm0, gauge_orig, shielding_nuc)