Structure and Spectroscopy of Copper−Dioxygen Complexes

“…Moreover, large variations in relative energies were observed when four, five, or six roots were employed in multistate calculations (see Table 2). Interestingly, reducing the symmetry to C i (which permits a greater mixing of the active and inactive orbitals in the CAS) leads to a smooth convergence and good agreement between active spaces of (12,12), (12,14), and (16,14) and also to good agreement between CASPT2 and MS-CASPT2 (i.e., interactions between multiple roots are rendered negligible). However, the converged energy of 1 0 relative to that of 1 100 is predicted to be -16.7 kcal mol -1 , which is very far from the CR-CC results.…”

“…[1][2][3][4][5][6][7][8] Tyrosinase 1,5,6,9 is one example of an enzyme whose active site incorporates a Cu 2 O 2 core, and substantial effort has also been devoted to the characterization of smaller inorganic models characterized by the same core. 2, [10][11][12][13][14][15][16][17][18] There are several motifs for the binding of molecular O 2 to two supported copper(I) atoms ( Figure 1). 12,19 Best characterized experimentally (because they have been observed for many different supporting ligand sets) are the side-on µ-η 2 :η 2 peroxo and the bis(µ-oxo).…”

“…2, [10][11][12][13][14][15][16][17][18] There are several motifs for the binding of molecular O 2 to two supported copper(I) atoms ( Figure 1). 12,19 Best characterized experimentally (because they have been observed for many different supporting ligand sets) are the side-on µ-η 2 :η 2 peroxo and the bis(µ-oxo). The trans end-on µ-η 1 :η 1 peroxo motif was first described by Jacobson et al 20 This binding mode is preferred when the copper atoms are supported by tripodal tetradentate ligands, [21][22][23][24][25] although when such ligands become too sterically demanding for trigonal bipyramidal coordination of copper a preference for the bis(µ-oxo) motif with concomitant loss of two ligand-copper interactions has been documented.…”

Theoretical Characterization of End-On and Side-On Peroxide Coordination in Ligated Cu₂O₂ Models

“…Moreover, large variations in relative energies were observed when four, five, or six roots were employed in multistate calculations (see Table 2). Interestingly, reducing the symmetry to C i (which permits a greater mixing of the active and inactive orbitals in the CAS) leads to a smooth convergence and good agreement between active spaces of (12,12), (12,14), and (16,14) and also to good agreement between CASPT2 and MS-CASPT2 (i.e., interactions between multiple roots are rendered negligible). However, the converged energy of 1 0 relative to that of 1 100 is predicted to be -16.7 kcal mol -1 , which is very far from the CR-CC results.…”

“…[1][2][3][4][5][6][7][8] Tyrosinase 1,5,6,9 is one example of an enzyme whose active site incorporates a Cu 2 O 2 core, and substantial effort has also been devoted to the characterization of smaller inorganic models characterized by the same core. 2, [10][11][12][13][14][15][16][17][18] There are several motifs for the binding of molecular O 2 to two supported copper(I) atoms ( Figure 1). 12,19 Best characterized experimentally (because they have been observed for many different supporting ligand sets) are the side-on µ-η 2 :η 2 peroxo and the bis(µ-oxo).…”

“…2, [10][11][12][13][14][15][16][17][18] There are several motifs for the binding of molecular O 2 to two supported copper(I) atoms ( Figure 1). 12,19 Best characterized experimentally (because they have been observed for many different supporting ligand sets) are the side-on µ-η 2 :η 2 peroxo and the bis(µ-oxo). The trans end-on µ-η 1 :η 1 peroxo motif was first described by Jacobson et al 20 This binding mode is preferred when the copper atoms are supported by tripodal tetradentate ligands, [21][22][23][24][25] although when such ligands become too sterically demanding for trigonal bipyramidal coordination of copper a preference for the bis(µ-oxo) motif with concomitant loss of two ligand-copper interactions has been documented.…”

Theoretical Characterization of End-On and Side-On Peroxide Coordination in Ligated Cu₂O₂ Models

“…2,3 Besides the biologically occurring side-on-bonded peroxide, the isomeric bis(m-oxo) dicopper(III) core (O core) has often been found in model complexes. 3,4 The most accepted mechanism, based on both theory and experimental data, proposes that a P core species performs the hydroxylation reaction through an electrophilic aromatic substitution reaction and that the cleavage of the O-O bond occurs either concerted with or after the C-O bond formation. 5 However, radical mechanisms have been proposed 6 and several examples of highly active pure O core complexes kept the discussion about the truly hydroxylating species in tyrosinase alive.…”

“…1) between O and P cores can be shifted by the choice of the ligands, temperature and counteranions. 3 Moreover this equilibrium is theoretically regarded as a torture track for computational chemistry, 8,9 since the amount of exact exchange heavily influences the predicted energies for the O/P equilibrium. 9 Several studies with multi-reference (MR) calculations based on a wave functional theory (WFT) method such as CASPT2, 10 MRCI + Q, 11 DMRG, 12 and RASPT2 13 have been carried out with ammonia ligands as a substitution for histidine residues.…”

Hiking on the potential energy surface of a functional tyrosinase model – implications of singlet, broken-symmetry and triplet description

Copper: Hemocyanin/Tyrosinase ModelsBased in part on the article Copper: Hemocyanin/Tyrosinase Models by Nobumasa Kitajima which appeared in the Encyclopedia of Inorganic Chemistry, First Edition .