Laser Photolysis of Chromium(lll) Porphyrins in Toluene Solutions. Effects of Oxygen on the Photodissociation Yields of the Axial Ligands

Inamo, Masahiko; Hoshino, Mikio

doi:10.1111/j.1751-1097.1999.tb08257.x

Cited by 8 publications

(35 citation statements)

References 31 publications

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“…Clearly, dioxygen plays a crucial role in nanoparticle synthesis in THF. Dioxygen has nearly equal solubility in toluene and THF (Bunsen solubility coefficients = 0.22 and 0.24, respectively , ), so the effect is not one of O 2 concentration, but of its absence. We next speculate on the role of O 2 in the reaction and the THF solvent.…”

Section: Resultsmentioning

confidence: 99%

Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations

Parker¹,

Weaver²,

McCallum³

et al. 2010

Langmuir

103

102

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A single phase (THF) synthesis of monodisperse [Oct(4)N(+)][Au(25)(SR)(18)(-)] nanoparticles is described that yields insights into pathways by which it is formed from initially produced larger nanoparticles. Including the Oct(4)N(+)Br(-) salt in a reported single phase synthetic procedure enables production of reduced nanoparticles having a fully occupied HOMO molecular energy level (Au(25)(SR)(18)(-), as opposed to a partially oxidized state, Au(25)(SR)(18)(0)). The revised synthesis accommodates several (but not all) different thiolate ligands. The importance of acidity, bromide, and dioxygen on Au(25) formation was also assessed. The presence of excess acid in the reaction mixture steers the reaction toward making Au(25)(SR)(18); while bromide does not seem to affect Au(25) formation, but it may play a role in maintaining the -1 oxidation state. Conducting the nanoparticle synthesis and "aging" period in the absence of dioxygen (under Ar) does not produce small nanoparticles, providing insights into the pathway of reaction product "aging" in the synthesis solvent, THF. The "aging" process favors the Au(25)(-) moiety as an end point and possibly involves degradation of larger nanoparticles by hydroperoxides formed from THF and oxygen.

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Section: Resultsmentioning

confidence: 99%

Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations

Parker¹,

Weaver²,

McCallum³

et al. 2010

Langmuir

103

102

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“…We have been particularly interested in the dynamics of the photoinduced axial ligand dissociation and association reaction of the chromium(III) porphyrins. Theoretical and photophysical studies revealed that the excited singlet and triplet states of the porphyrin π system weakly interact with the central chromium atom ( S = 3/2) to give 4 S 1 , 2 T 1 , 4 T 1 , and 6 T 1 excited states and that the lowest and second lowest excited states, 6 T 1 and 4 T 1 , are in thermal equilibrium. , Meanwhile, laser photolysis of chromium(III) porphyrins in solution causes photoinduced axial ligand ejection as well as other various photoinduced phenomena. − Since the photodissociated ligand undergoes a recombination reaction to yield the parent metalloporphyrins, laser photolysis is one of the key methods to elucidate the dynamics of the axial ligand binding. An earlier study has shown that the axial ligand of chromium(III) porphyrins is fairly labile compared with those of other chromium(III) complexes having non-porphyrin ligands .…”

Section: Introductionmentioning

confidence: 99%

Laser Photolysis Studies of the Photochemical Reactions of Chromium(III) Octaethylporphyrin and Tetramesitylporphyrin Complexes in Toluene Solution

et al. 2003

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A nanosecond laser photolysis study was carried out for the Cr(III) porphyrin complexes of 2,3,7,8,12,13,17,18-octaethylporphyrin, [Cr(OEP)(Cl)(L)], and of 5,10,15,20-tetramesitylporphyrin, [Cr(TMP)(Cl)(L)], in toluene containing water and an excess amount of L (L = axial ligand). The laser photolysis generates the triplet excited state of the parent complex as well as a five-coordinate complex, [Cr(porphyrin)(Cl)], produced by the photodissociation of the axial ligand L. The yields for the formation of the triplet state and the photodissociation of L are found to markedly depend on the nature of both L and porphyrin ligand. The five-coordinate [Cr(porphyrin)(Cl)] readily reacts with both H(2)O and L in the bulk solution to give [Cr(porphyrin)(Cl)(H(2)O)] and [Cr(porphyrin)(Cl)(L)], respectively. The axial H(2)O ligand in [Cr(porphyrin)(Cl)(H(2)O)] is then substituted by the ligand L to regenerate the original complex [Cr(porphyrin)(Cl)(L)]. In principle, the substitution reaction takes place by the dissociative mechanism: the first step is the dissociation of H(2)O from [Cr(porphyrin)(Cl)(H(2)O)], followed by the reaction of the five-coordinate [Cr(porphyrin)(Cl)] with the ligand L to regenerate [Cr(porphyrin)(Cl)(L)]. The rate constants for this ligand substitution reaction are found to exhibit bell-shaped ligand concentration dependence. The detailed kinetic analysis revealed that both ligands L and H(2)O in toluene make a hydrogen bond with the axial H(2)O ligand in [Cr(porphyrin)(Cl)(H(2)O)] to yield dead-end complexes for the substitution reaction. The reaction mechanisms are discussed on the basis of the substituent effects of the porphyrin peripheral groups and the kinetic parameters determined from the temperature dependence of the rate constants.

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“…The rate for the decay of the triplet state is much faster than that of (I - )Rh III TPP, and thus, the transient spectrum for the triplet state is obtained by subtracting the transient spectrum measured at 2 μs from that at 30 ns. With the use of the absorbances, D T (λ) and D 0 (λ), of the excited triplet state and the ground state of (I - )(PPh 3 )Rh III TPP at the wavelength λ, the absorbance change, Δ D (λ), of the transient spectrum of the triplet state is expressed as , The variable number, k , is the function of the energy of a laser pulse and ranges 0 < k < 1.0. Equation 9 is transformed to If k is appropriate, the plot of D T (λ) vs λ gives the absorption spectrum of 3 [(I - )(PPh 3 )Rh III TPP]*.…”

Section: Resultsmentioning

confidence: 99%

“…Equation 9 is transformed to If k is appropriate, the plot of D T (λ) vs λ gives the absorption spectrum of 3 [(I - )(PPh 3 )Rh III TPP]*. We assume here that the triplet spectrum of (I - )(PPh 3 )Rh III TPP in the Soret band region is not distorted. , The value k = 0.6 ± 0.05 gives a smooth absorption band centered at 490 nm. Thus, the triplet absorption spectrum is obtained by the plot of D T (λ) vs λ at k = 0.6 ± 0.05.…”

Section: Resultsmentioning

confidence: 99%

“…Femtosecond laser photolysis of [Fe III P] + , [Co III P] + , and Ni II P 34 suggests that the dissociation of axial ligands occurs from the d−d*, MLCT, or LMCT excited states. Nanosecond photolysis of (Cl - )(L)Cr III P (L = axial ligand) revealed that the axial ligand L is dissociated from both the 4 S 1 and the 6 T 1 (and/or 4 T 1 ) state . Alkylindium(III) porphyrins have been confirmed to dissociate the alkyl group via the excited triplet state originating from the porphyrin ligand …”

Section: Discussionmentioning

confidence: 99%

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Laser Photolysis Studies of Rhodium(III) Porphyrins. Photodissociation of Axial Phosphine Ligand in the Temperature Range 300−200 K

2003

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Photodissociation of the axial ligand from triphenylphosphine complexes of rhodium(III) octaethyl- and tetraphenyporphyrin halides, (X-)(PPh3)RhIIIOEP and (X-)(PPh3)RhIIITPP (X = Cl, Br, and I), in toluene solutions are investigated by the 355-nm laser flash photolysis. The photodissociation yield of PPh3, Φ, from (X-)(PPh3)RhIIIOEP is markedly dependent on the nature of X: Φ = 0.79 for X = I, Φ = 0.48 for X = Br, and Φ = 0 for X = Cl. Similar trends are observed for (X-)(PPh3)RhIIITPP: Φ = 0.13 for X = I and Φ = 0 for X = Br and Cl. The excited triplet state is not detected for (I-)(PPh3)RhIIIOEP and (Br-)(PPh3)RhIIIOEP but for (Cl-)(PPh3)RhIIIOEP and (X-)(PPh3)RhIIITPP. On the basis of the oxygen quenching study and the temperature dependence of the dissociation quantum yields, the excited state of (I-)(PPh3)RhIIIOEP and (Br-)(PPh3)RhIIIOEP from which the dissociation occurs is ascribed to the excited singlet state. For (I-)(PPh3)RhIIITPP, either the excited singlet and triplet state is found to be responsible for the dissociation of the axial PPh3. From the quantum yield measurements for the photodissociation of the axial PPh3, Φ, and the triplet formation, ΦST, in the temperature range 200−300 K, the ligand dissociation and the intersystem crossing processes of (I-)(PPh3)RhIIITPP are demonstrated to be competitive at the excited singlet state. The sum of the quantum yields, Φ plus ΦST, obtained at 300 K is smaller than unity. This result is discussed by assuming that the energy dissipation process at the excited singlet state is due to the formation of the transient species that have insufficiently dissociated bonds between X and Rh and/or PPh3 and Rh: the species partly return to the parent molecule without dissociation of the axial PPh3.

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Laser Photolysis of Chromium(lll) Porphyrins in Toluene Solutions. Effects of Oxygen on the Photodissociation Yields of the Axial Ligands

Cited by 8 publications

References 31 publications

Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations

Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations

Laser Photolysis Studies of the Photochemical Reactions of Chromium(III) Octaethylporphyrin and Tetramesitylporphyrin Complexes in Toluene Solution

Laser Photolysis Studies of Rhodium(III) Porphyrins. Photodissociation of Axial Phosphine Ligand in the Temperature Range 300−200 K

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Laser Photolysis of Chromium(lll) Porphyrins in Toluene Solutions. Effects of Oxygen on the Photodissociation Yields of the Axial Ligands

Cited by 8 publications

References 31 publications

Synthesis of Monodisperse [Oct4N+][Au25(SR)18−] Nanoparticles, with Some Mechanistic Observations

Synthesis of Monodisperse [Oct4N+][Au25(SR)18−] Nanoparticles, with Some Mechanistic Observations

Laser Photolysis Studies of the Photochemical Reactions of Chromium(III) Octaethylporphyrin and Tetramesitylporphyrin Complexes in Toluene Solution

Laser Photolysis Studies of Rhodium(III) Porphyrins. Photodissociation of Axial Phosphine Ligand in the Temperature Range 300−200 K

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Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations

Synthesis of Monodisperse [Oct₄N⁺][Au₂₅(SR)₁₈⁻] Nanoparticles, with Some Mechanistic Observations