Facile Conversion of syn‐[FeIV(O)(TMC)]2+ into the anti Isomer via Meunier's Oxo–Hydroxo Tautomerism Mechanism

The syn and anti isomers of [Fe^IV(O)(TMC)]²⁺ (TMC=tetramethylcyclam) represent the first isolated pair of synthetic non‐heme oxoiron(IV) complexes with identical ligand topology, differing only in the position of the oxo unit bound to the iron center. Both isomers have previously been characterized. Reported here is that the syn isomer [Fe^IV(O_syn)(TMC)(NCMe)]²⁺ ( 2 ) converts into its anti form [Fe^IV(O_anti)(TMC)(NCMe)]²⁺ ( 1 ) in MeCN, an isomerization facilitated by water and monitored most readily by ¹H NMR and Raman spectroscopy. Indeed, when H₂¹⁸O is introduced to 2 , the nascent 1 becomes ¹⁸O‐labeled. These results provide compelling evidence for a mechanism involving direct binding of a water molecule trans to the oxo atom in 2 with subsequent oxo–hydroxo tautomerism for its incorporation as the oxo atom of 1 . The nonplanar nature of the TMC supporting ligand makes this isomerization an irreversible transformation, unlike for their planar heme counterparts.     

An Iron(III)–Catechol Complex as a Mushroom Pigment

An iron ink has been detected as the pigment of the beautiful dark violet mushroom Cortinarius violaceus. The amino acid (R)-β-dopa ( 1 ) is the ligand of the 1:2 Feⁱⁱⁱ –catechol complex.     

Coprecipitation of iron and platinum(IV) hydroxo complexes as probed by Mössbauer spectroscopy

Stabilization of ⁵⁷Fe compounds in matrices of solid solutions of platinum(IV) superoxo- and hydroxo complexes was probed by Mössbauer spectroscopy. The ratio Fe^III/Fe^IV in these matrices is 20/1.     

Thermodynamics and Kinetics of Reaction of (Oxo)(hydroxo)molybdenumtetraphenylporphyrin with Pyridine

The reaction of meso-tetraphenylporphyrin with Mo(VI) oxide in boiling phenol resulted in a stable complex O=Mo(OH)TPP. Thermodynamics and kinetics of the reaction between (oxo)(hydroxo)molybdenumtetraphenyporphyrin with pyridine in toluene were studied by spectrophotometric method. This reaction was found to occur in three equilibrium elementary stages: replacement of OH^– by Py (K ₁=9.1 × 10³ l/mol, k ₁=5.25 s^–1 mol^–1 l), the formation of dication (dipyridine)(hydroxo)molybdenumtetraphenylporphyrin as a result of cleavage of a double bond Mo=O (K ²=39.3 l/mol, k ₂=1.83 × 10^–2 s^-1 mol^–1 l), and the formation of cationic complex[Mo(Py)₃TPP]³⁺ · 3OH^– (K ₃=1.0 l/mol, k ₃=1.19 × 10^–3 s^–1 mol^–1 l).__________Translated from Koordinatsionnaya Khimiya, Vol. 31, No. 5, 2005, pp. 380–386.Original Russian Text Copyright © 2005 by Tipugina, Lomova, Motorina.     

Synthesis,Structure and Magnetic Property of an “Adamantane” Type Tetranuclear Iron(III) Complex

A new tetranuclear complex [Fe₄ L ₂(μ‐O)₂(μ‐>OH)₂](ClO₄)₄·H₂O ( 1 ), (H L = N,N,N′,N′‐tetrakis‐[(2‐pyridyl)methyl]‐2‐hydroxypropane‐1,3‐diamine) has been synthesized and its crystal structure and magnetic properties are shown. X‐ray crystallography reveals that complex 1 contains a quadruply‐charged, tetranuclear iron(III) cation and four perchlorate anions. In 1 , the Fe₄O₆ core is composed of a tetrahedron of iron atoms bridged by six oxygen atoms (two oxo, two hydroxo, and two alkoxo groups from L ). This results in an adamantane‐type geometry with the iron atoms occupying the bridgehead positions. Susceptibility data of 1 indicate strong intramolecular antiferromagnetic coupling of high‐spin Fe^III atoms.     

Effect of Heme–Heme Interactions and Modulation of Metal Spins by Counter Anions in a Series of Diiron(III)‐μ‐hydroxo Bisporphyrins: Unusual Stabilization of Two Different Spins in a Single Molecular Framework

A new family of five ethene‐bridged diiron(III)‐μ‐hydroxo bisporphyrins with the same core structure but different counter anions, represented by the general formula [Fe₂(bisporphyrin)]OH ? X (X=counter anion), is reported herein. In these complexes, two different spin states of Fe are stabilized in a single molecular framework. Protonation of the oxo‐bridged dimer 1 by strong Brønsted acids such as HI, HBF₄, HPF₆, HSbF₆, and HClO₄ produces the μ‐hydroxo complexes with I₅^? ( 2 ), BF₄^? ( 3 ), PF₆^? ( 4 ), SbF₆^? ( 5 ), and ClO₄^? ( 6 ) as counter anions, respectively. The X‐ray structures of 2 and 6 have been determined, which provide a rare opportunity to investigate structural changes upon protonation. Spectroscopic characterization has revealed that the two iron(III) centers in 2 are nonequivalent with nearly high and admixed‐intermediate spins in both the solid state and solution. Moreover, the two different Fe^III centers of 3 – 5 are best described as having admixed‐high and admixed‐intermediate spins with variable contributions of S=5/2 and 3/2 for each state in the solid, but two different admixed‐intermediate spins in solution. In contrast, the two Fe^III centers in 6 are equivalent and are assigned as having high and intermediate spin states in the solid and solution, respectively. The X‐ray structures reveal that the Fe? O bond length increases on going from the μ‐oxo to the μ‐hydroxo complexes, and the Fe‐O(H)‐Fe unit becomes more bent, with the dihedral angle decreasing from 150.9(2)° in 1 to 142.3(3)° and 143.85(2)° in 2 and 6 , respectively. Variable‐temperature magnetic data have been subjected to a least‐squares fitting using the expressions derived from the spin Hamiltonians H=?2JS₁?S₂?μ?B+D[${S{{2\hfill \atop z\hfill}}}$ ?1/3S(S+1)] (for 2 , 3 , 4 , and 5 ) and H=?2JS₁?S₂ (for 6 ). The results show that strong antiferromagnetic coupling between the two Fe^III centers in 1 is attenuated to nearly zero (?2.4 cm^?1) in 2 , whereas the values are ?46, ?32.6, ?33.5, and ?34 cm^?1 for 3 , 4 , 5 , and 6 , respectively.     

A pH- and Redox-Potentiometric Study of Equilibria between Fe(II), Fe(III), and N-(Carboxymethyl)Aspartic Acid

Complexation in the Fe²⁺–Fe³⁺–N-(carboxymethyl)aspartic acid (H₃L) system in aqueous solutions was studied by pH- and redox-potentiometric titration at 25°C and at an ionic strength of 0.1 (KCl). Depending on the H₃L concentration and pH, neutral, protonated, and hydroxo complexes of iron(III) can be formed in the solutions. The stability constants for all the detected complexes were calculated, and the distribution plots for the fractions of complexes vs. the solution pH were constructed.     

The Building Block [FeIII(pzphen)(CN)4]– and its Lanthanide Complexes: Synthesis,Crystal Structure,and Magnetic Properties

The cyanide building block [Fe^III(pzphen)(CN)₄]^– and its four lanthanide complexes [{Fe^III(pzphen)(CN)₄}₂Ln^III(H₂O)₅(DMF)₃] · (NO₃) · 2(H₂O) · (CH₃CN) [Ln = Nd ( 1 ), Sm ( 2 ), DMF = dimethyl formamide] and [{Fe^III(pzphen)(CN)₄}₂Ln^III(NO₃)(H₂O)₂(DMF)₂](CH₃CN) [Ln = Gd ( 3 ), Dy ( 4 )] were synthesized and structurally characterized by single‐crystal X‐ray diffraction. Compounds 1 and 2 are ionic salts with two [Fe^III(pzphen)(CN)₄]^– cations and one Ln^III ion, but compounds 3 and 4 are cyano‐bridged Fe^III‐Ln^III heterometallic 3d‐4f complexes exhibiting a trinuclear structure in the same conditions. Magnetic studies show that compound 3 is antiferromagnetic between the central Fe^III and Gd^III atoms. Furthermore, the trinuclear cyano‐bridged Fe^III₂Dy^III compound 4 displays no single‐molecular magnets (SMMs) behavior by the alternating current magnetic susceptibility measurements.     

Synthesis and structure of the cluster Fe2Mo2(μ3-Se)(μ3-AsMe)(μ3-Co)(μ-Co)(Co)5(η5-Cp)2

The reaction of (Et₄N)₂[Fe₃(μ₃-Se)(Co)₉] with MeAsI₂ afforded the [Fe₃(μ₃-Se)(μ₃-AsMe)(Co)₉] cluster, which was characterized by¹H NMR and IR spectroscopy and elemental analysis. The reaction of the resulting compound with the dimeric, complex [η⁵-CpMo(CO)₃#x005D;₂ inm-xylene upon refluxing gave the heterometallic cluster Fe₂Mo₂(μ₃-Se)(μ₃-AsMe)(μ₃-Co)(μ-Co)(Co)₅(η⁵-Cp)₂, whose structure was established by X-ray diffraction analysis. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 5, pp. 996–998, May, 1999.     

Protonation of an Oxo‐Bridged Diiron Unit Gives Two Different Iron Centers: Synthesis and Structure of a New Class of Diiron(III)‐μ‐hydroxo Bisporphyrins and the Control of Spin States by Using Counterions

Reported herein is a hitherto unknown family of diiron(III)‐μ‐hydroxo bisporphyrins in which two different spin states of Fe are stabilized in a single molecular framework, although both cores have identical molecular structures. Protonation of the oxo‐bridged dimer ( 2 ) by using strong Brønsted acids, such as HI, HBF₄, and HClO₄, produce red μ‐hydroxo complexes with I₃^? ( 3 ), BF₄^? ( 4 ), and ClO₄^? ( 5 ) counterions, respectively. The X‐ray structure of the molecule reveals that the Fe? O bond length increases on going from the μ‐oxo to the hydroxo complex, whereas the Fe‐O(H)‐Fe unit becomes more bent, which results in the smallest known Fe‐O(H)‐Fe angles of 142.5(2) and 141.2(1)° for 3 and 5 , respectively. In contrast, the Fe‐O(H)‐Fe angle remains unaltered in 4 from the corresponding μ‐oxo complex. The close approach of two rings in a molecule results in unequal core deformations in 3 and 4 , whereas the cores are deformed almost equally but to a lesser extent in 5 . Although 3 was found to have nearly high‐spin and admixed intermediate Fe spin states in cores I and II, respectively, two admixed intermediate spin states were observed in 4 . Even though the cores have identical chemical structures, crucial bond parameters, such as the Fe? N_p, Fe? O, and Fe???Ct_p bond lengths and the ring deformations, are all different between the two Fe^III centers in 3 and 4 , which leads to an eventual stabilization of two different spin states of Fe in each molecule. In contrast, the two Fe centers in 5 are equivalent and assigned to high and intermediate spin states in the solid and solution states, respectively. The spin states are thus found to be dependent on the counterions and can also be reversibly interconverted. Upon protonation, the strong antiferromagnetic coupling in the μ‐oxo dimer (J, ?126.6 cm^?1) is attenuated to almost zero in the μ‐hydroxo complex with the I₃^? counterion, whereas the values of J are ?36 and ?42 cm^?1, respectively, for complexes with BF₄^? and ClO₄^? counterions.     

Effect of Inter‐Porphyrin Distance on Spin‐State in Diiron(III) μ‐Hydroxo Bisporphyrins

The synthesis, structure, and properties of bischloro, μ‐oxo, and a family of μ‐hydroxo complexes (with BF₄^?, SbF₆^?, and PF₆^? counteranions) of diethylpyrrole‐bridged diiron(III) bisporphyrins are reported. Spectroscopic characterization has revealed that the iron centers of the bischloro and μ‐oxo complexes are in the high‐spin state (S=⁵/₂). However, the two iron centers in the diiron(III) μ‐hydroxo complexes are equivalent with high spin (S=⁵/₂) in the solid state and an intermediate‐spin state (S=³/₂) in solution. The molecules have been compared with previously known diiron(III) μ‐hydroxo complexes of ethane‐bridged bisporphyrin, in which two different spin states of iron were stabilized under the influence of counteranions. The dimanganese(III) analogues were also synthesized and spectroscopically characterized. A comparison of the X‐ray structural parameters between diethylpyrrole and ethane‐bridged μ‐hydroxo bisporphyrins suggest an increased separation, and hence, less interactions between the two heme units of the former. As a result, unlike the ethane‐bridged μ‐hydroxo complex, both iron centers become equivalent in the diethylpyrrole‐bridged complex and their spin state remains unresponsive to the change in counteranion. The iron(III) centers of the diethylpyrrole‐bridged diiron(III) μ‐oxo bisporphyrin undergo very strong antiferromagnetic interactions (J=?137.7 cm^?1), although the coupling constant is reduced to only a weak value in the μ‐hydroxo complexes (J=?42.2, ?44.1, and ?42.4 cm^?1 for the BF₄, SbF₆, and PF₆ complexes, respectively).     

Vibrational Properties of [FeH(N2)(depe)2]+ and [FeCl(N2)(depe)2]+]: Dinitrogen Bonding in the Low Activation Limit

The vibrational properties of the two octahedral Fe^II dinitrogen complexes [FeH(N₂)(depe)₂]⁺ ( 1 ) and [FeCl(N₂)(depe)₂]⁺ ( 2 , depe = 1, 2‐bis(diethylphosphino)ethane) are investigated with the help of infrared and Raman spectroscopies. Vibrational data are evaluated with a Quantum Chemistry Assisted Normal Coordinate Analysis (QCA‐NCA; N. Lehnert, F. Tuczek, Inorg. Chem. 1999 , 38, 1659). In agreement with high values found for ν(NN) and the corresponding force constants f(NN), the N₂ ligands in compounds 1 and 2 are non‐activated which corresponds to the observation that N₂ is not protonable in Fe^II systems. Taking into account the short Fe‐N bond lengths, the values of the Fe‐N stretching force constants (2.55mdyn/Å for 1 and 2.58mdyn/Å for 2 ) are found to be compatible with those of other Fe^II low‐spin compounds coordinated to backbonding N‐coordinating ligands. The force fields obtained for the Fe‐N₂ units of 1 and 2 are almost identical although the thermal stability of 1 and 2 with respect to loss of N₂ is different. This indicates that the zero‐point vibrational levels are unaffected by possible ground‐state level crossing processes occuring at larger Fe‐N bond lengths, as observed for 2 (O. Franke, B. E. Wiesler, N. Lehnert, C. Näther, V. Ksenofontov, J. Neuhausen, F. Tuczek, Inorg. Chem. 2002 , 41, 3491).     

Amine-containing tertiary phosphine-substituted diiron ethanedithioate (edt) complexes Fe2(μ-edt)(CO)6-nLn (n= 1, 2): Synthesis,protonation, and electrochemical properties

As diiron subsite models of [FeFe]-hydrogenases for catalytic proton reduction to hydrogen (H₂), a new series of the phosphine-substituted diiron ethanedithiolate complexes Fe₂(μ-edt)(CO)_6-nL_n (n = 1, 2) were prepared from the variable substitutions of all-CO precursor Fe₂(μ-edt)(CO)₆ ( A ) and tertiary phosphines (L1-L4) under different reaction conditions. While the Me₃NO-assisted substitutions of A and one equiv. ligands L1-L4 [L = Ph₂P(CH₂NHBu^t), Ph₂P(CH₂CH₂NH₂), Ph₂P(NHBu^t), and Ph₂P(C₆H₄Me-p)] produced the monosubstituted complexes Fe₂(μ-edt)(CO)₅L ( 1 – 4 ) in good yields, the refluxing xylene solution of A and two equiv. ligand L1 prepared complex Fe₂(μ-edt)(CO)₅{κ¹-Ph₂P(CH₂NHBu^t)} ( 1 ) in low yield. Meanwhile, the UV-irradiated toluene solution of A and two equiv. ligand L3 resulted in the rare formation of the disubstituted complex Fe₂(μ-edt)(CO)₄{κ¹, κ¹-(Ph₂PNHBu^t)₂} ( 5 ) in low yield, whereas the Me₃NO-assisted substitution of A and two equiv. ligand L4 afforded the disubstituted complex Fe₂(μ-edt)(CO)₄{κ¹, κ¹-(Ph₂PC₆H₄Me-p)₂} ( 6 ) in good yield. All the model complexes 1 – 6 have been characterized by elemental analysis, FT-IR, NMR spectroscopy, and particularly for 1 , 3 , 5 by X-ray crystallography. Further, the protonations of complexes 1 – 4 are studied and compared with excess acetic acid (HOAc) and trifluoroacetic acid (TFA) by using FT-IR and NMR techniques. Additionally, the electrochemical and electrocatalytic properties of model complexes 1 – 6 are investigated and compared by cyclic voltammetry (CV), suggesting that they are electrocatalytically active for proton reduction to H₂ in the presence of HOAc.     

Synthesis, structure, and properties of a binuclear Fe(III) complex with N-(1-propanol)-N,N-bis(3-tert-butyl-5-methyl-2-hydroxybenxyl)amine

Mannich reaction of 2-Amino propanol, 2-tert-butyl-4-methylphenol, and formaldehyde in the ratio of 1:2:2 provides a new compound, N-(1-propanol)-N,N-bis(3-tert-butyl-5-methyl-2-hydroxybenxyl)amine (H₃L), which has been characterized by X-ray crystallography and elemental analysis. In the presence of Et₃N, the reaction of H₃L and FeCl₃·6H₂O gives a dinuclear Fe(III) complex [Fe₂L₂] 1, which has been characterized by X-ray crystallography, magnetic measurement, and cyclic voltammetry. The value of μ_eff at room temperature (5.97 μ_B) is much less than the expected spin-only value (8.37 μ_B) of two high spin (hs) Fe³⁺ (S = 5/2) ions [μ = g[∑ZS(S + 1)]^1/2], indicating there are strong coupling interactions between Fe³⁺ ions. The magnetic behavior of 1 denotes the occurrence of intramolecular antiferromagnetic interactions (J = −13.35 cm⁻¹ ). CV of 1 reveals two reversible waves at 0.433 and 1.227 V versus AgCl/Ag, which can be ascribed to the successive redox coupling of Fe^IIFe^II/Fe^IIIFe^II and Fe^IIIFe^II/Fe^IIIFe^III, respectively.     

The kinetics of aquation and racemization of some cis- chloro-, hydroxo-, and aquabis(ethylenediamine)(amine)cobalt(III) complexes

Aquation rates forcis-CoCl(en)₂(A)²⁺ (A = 3,5-lutidine, imidazole, N-methylimidazole, benzimidazole) have been determined by halide release titration in 1.0 M HNO₃ at 50–80°C. Kinetic parameters are (in the above order of A) 10⁷k₂₉₈ (sec^?1), 7.4, 5.7, 1.3, 9.7; E_a (kJ/mole), 103, 101, 130, 112; log PZ (sec^?1), 11.89, 11.53, 16.04, 13.58; ΔS₂₉₈^? (J/°K· mole),?26, ?32, +54,+7. Rates of racemization for active cis-Co(en)₂(A)-(OH₂)³⁺ were measured spectropolarimetrically in 0.1 M HClO₄, 0.02 M Hg²⁺ for A = ammonia, cyclohexylamine, 3,5-lutidine, N-methylimidazole. Kinetic parameters are (units as above) 10⁹k₂₉₈ = 1.8, 38.0, 7.7, 1.7; E_a = 150, 135, 152, 157; log PZ = 17.49, 16.18, 18.56, 18.87; ΔS₂₉₈^? = +82, +57, +102,+108. Rates of racemization of the active hydroxo complexes cis-Co(en)₂(A)(OH)²⁺ (A = NH₃, CH₃NH₂, 3,5-lutidine, imidazole) were measured similarly at pH = 8 (π = 2.0, NaClO₄). The racemization of the hydroxo is ca. (3–4) × 10³ faster than for the corresponding aqua complex. Kinetic parameters are 10⁶k₂₉₈ = 2.55, 7.2, 30.1, 7.0; E_a = 138, 123, 122, 128; log PZ = 18.58, 16.39, 16.85, 17.18; ΔS₂₉₈^? = +102,+60, +69,+76. Racemization rates for aquahydroxo mixtures (A = CH₃NH₂, 3,5-lutidine, imidazole) were also determined in the pH range of 4–8 (θ = 2.0, NaClO₄) at 50.6°C, and pK_a data calculated from the pH versus k plot are 5.50, 5.65, and 6.40, respectively, for A.     

Reactions of Fe2(μ‐odt)(CO)6 (odt = 1, 3‐oxadithiolate) with small bite‐angle diphosphines to afford the monodentate,chelate, and bridge diiron complexes: Selective substitution,structures, protonation,and electrocatalytic proton reduction

Selective substitutions of Fe₂(μ‐odt)(CO)₆ (odt = 1,3‐oxadithiolate, A ) and small bite‐angle diphosphines (Ph₂P)₂X [X = CH₂ (dppm) or N (CH₂CHMe₂) (dppa)] have been well investigated in this study. With Me₃NO·2H₂O in MeCN at room temperature, the reaction of A and dppm produced the monodentate complex [Fe₂(μ‐odt)(CO)₅(κ¹‐dppm)] ( 1 ), whereas the similar reaction with dppa afforded the chelate complex [Fe₂(μ‐odt)(CO)₄(κ²‐dppa)] ( 2 ). Using UV irradiation in toluene emitting at 365 nm, the treatment of A and dppm rarely resulted in the formation of the bridge complex [Fe₂(μ‐odt)(CO)₄(μ‐dppm)] ( 3 ), whereas the similar treatment with dppa formed the chelate complex 2 . Under thermolysis condition, refluxing solution of A with dppm or dppa gave the bridge complex 3 and [Fe₂(μ‐odt)(CO)₄(μ‐dppa)] ( 4 ), respectively, in which the former was formed in toluene (110 °C) but the latter was produced in xylene (138 °C). All the new complexes 1 – 4 obtained above were characterized by element analysis, FT‐IR, NMR (¹H, ³¹P) spectroscopies, and particularly for 1 – 3 by X‐ray crystallography. Furthermore, the in situ protonations of 2 with a weak acid HOAc (acetic acid) and a strong acid TFA (trifluoroacetic acid) are explored by means of FT‐IR and NMR (¹H, ³¹P) spectra. In addition, the electrochemical behaviors of 2 – 4 are studied and compared through cyclic voltammetry (CV) in the absence and presence of a strong acid (TFA) as a proton source, indicating that they all are active for electrocatalytic proton reduction to hydrogen (H₂).     

Komplexone XLII. Die Untersuchung der 1:1:-Komplexe von einigen drei-und vierwertigen Metall-Ionen mit Polyaminocarboxylaten mittels Redoxmessungen

The formation of complexes of Ga^III, In^III, Bi^III, Sc^III, Zr^IV, and Th^IV with polyaminocarboxylate ions was investigated using potentiometric measurements with the redox couples Fe³⁺/Fe²⁺ and Tl³⁺/Tl⁺. Some data concerning the formation of related hydroxo and hydrogen complexes are reported.     

Influence of Central Metalloligand Geometry on Electronic Communication between Metals: Syntheses,Crystal Structures,MMCT Properties of Isomeric Cyanido‐Bridged Fe2Ru Complexes,and TDDFT Calculations

To investigate how the central metalloligand geometry influences distant or vicinal metal‐to‐metal charge‐transfer (MMCT) properties of polynuclear complexes, cis‐ and trans‐isomeric heterotrimetallic complexes, and their one‐ and two‐electron oxidation products, cis/trans‐ [Cp(dppe)Fe^IINCRu^II(phen)₂CN‐Fe^II(dppe)Cp][PF₆]₂ (cis/trans‐ 1 [PF₆]₂), cis/trans‐[Cp(dppe)Fe^IINCRu^II(phen)₂CNFe^III‐(dppe)Cp][PF₆]₃ (cis/trans‐ 1 [PF₆]₃) and cis/trans‐[Cp(dppe)Fe^IIINCRu^II(phen)₂CN‐Fe^III(dppe)Cp][PF₆]₄ (cis/trans‐ 1 [PF₆]₄) have been synthesized and characterized. Electrochemical measurements show the presence of electronic interactions between the two external Fe^II atoms of the cis‐ and trans‐isomeric complexes cis/trans‐ 1 [PF₆]₂. The electronic properties of all these complexes were studied and compared by spectroscopic techniques and TDDFT//DFT calculations. As expected, both mixed valence complexes cis/trans‐ 1 [PF₆]₃ exhibited different strong absorption signals in the NIR region, which should mainly be attributed to a transition from an MO that is delocalized over the Ru^II‐CN‐Fe^II subunit to a Fe^III d orbital with some contributions from the co‐ligands. Moreover, the NIR transition energy in trans‐ 1 [PF₆]₃ is lower than that in cis‐ 1 [PF₆]₃, which is related to the symmetry of their molecular orbitals on the basis of the molecular orbital analysis. Also, the electronic spectra of the two‐electron oxidized complexes show that trans‐ 1 [PF₆]₄ possesses lower vicinal Ru^II→Fe^III MMCT transition energy than cis‐ 1 [PF₆]₄. Moreover, the assignment of MMCT transition of the oxidized products and the differences of the electronic properties between the cis and trans complexes can be well rationalized using TDDFT//DFT calculations.     

Hydrothermal synthesis,thermal decomposition and optical properties of Fe2F5(H2O)(Htaz)(taz)(Hdma)

Crystal structure of Fe₂F₅(H₂O)(Htaz)(taz)(Hdma) which crystallizes in the triclinic system space group $\text{P}\overline{1}$ with unit cell parameters a = 8.8392(5) Å, b = 9.1948(5) Å, c = 9.5877(5) Å, α = 82.070(3)°, β = 63.699(3)°, γ = 89.202(3)°, Z = 2, and V = 690.91(7) ų, was synthesized under hydrothermal conditions at 393 K for 72 h, by a mixture of FeF₂/FeF₃, 1,2,4-triazole molecule (Htaz), and hydrofluoric acid solution (HF 4%) in dimethylformamide solvent (DMF). The main feature of this material is the coexistence of two oxidation states for iron atoms (Fe²⁺, Fe³⁺) in the unit cell, which associate by opposite fluorine corners of FeF₅N and FeF₂N₄ octahedra, and/or triazole molecule which originates the 2D produces material. The structure determination, performed from single crystal X-ray diffraction data, lead to the R₁/_WR₂ reliability factors 0.031/0.087. Thermal stability studies (TG/DTG/DTA) show that the decomposition provides in the temperature range 473–773 K and no mass loss was detected before 473 K. Mass spectrometry (MS) has been used. The optical absorption of the solid was measured at the corresponding λ_max using UV–vis diffuse-reflectance spectrum.     

Synthesis and Characterization of Monomeric Aryloxo Palladium Complexes of the Type [Pd(N–N)(OAr)(C6F5)]. Crystal Structure of [Pd(tmeda)(C6F5)(OC6H4NO2‐p)]

Mononuclear palladium‐hydroxo complexes of the type [Pd(N–N)(C₆F₅)(OH)][(N–N) = 2,2′‐bipyridine (bipy), 4,4′‐dimethyl‐2,2′‐bipyridine (Me₂bipy), 1,10‐phenantroline (phen) or N,N,N′,N′‐tetramethylethylenediamine (tmeda) react with phenols ArOH in tetrahydrofuran giving the corresponding aryloxo complexes [Pd(N–N)(C₆F₅)(OAr)]. Elemental analyses and spectroscopic (IR, ¹H and ¹⁹F) methods have been used to characterize the new complexes. The X‐ray crystal structure of [Pd(tmeda)(C₆F₅)(OC₆H₄NO₂‐p)] has been determined. In the crystal packing the planes defined by two C₆H₄ rings show a parallel orientation. There are also intermolecular C–H···F and C‐H···O hydrogen bonds.