1-Benzyl-4-((phenylthio)-/(phenylseleno)methyl)-1H-1,2,3-triazole (L1/L2) and 4-phenyl-1-((phenylthio)-/(phenylseleno)methyl)-1H-1,2,3-triazole (L3/L4) synthesized
using the click reaction have been reacted for the first time with
[{(η6-C6H6)RuCl(μ-Cl)}2] and NH4PF6 to design the half-sandwich
complexes [(η6-benzene)RuLCl]PF6 (1–4 for L = L1–L4), which have been characterized
by single-crystal X-ray diffraction and explored for the catalytic
oxidation of alcohols with N-methylmorpholine N-oxide (NMO) and transfer hydrogenation of ketones with
2-propanol. There is a pseudo-octahedral “piano-stool”
disposition of donor atoms around Ru in 1–4. In 1 and 2, N(3) of the triazole
skeleton coordinates with Ru, whereas in other complexes the nitrogen
involved is N(2). The Ru–S and Ru–Se bond distances
are 2.3847(11)/2.3893(10) and 2.497(5)/2.4859(9) Å, respectively.
The catalytic processes are more efficient with 3 and 4 (compared to 1 and 2), in which
N(2) of the triazole is involved in coordination with Ru. The nature
of the chalcogen and steric factors together also appear to affect
the efficiency of complexes. HOMO–LUMO energy gaps are lower
for 3 and 4 than for 1 and 2. The formation of RuIVO species probably
results in oxidation and transfer hydrogenation involves an intermediate
containing Ru–H. Bond distances and angles based on DFT calculations
are generally consistent with experimental values.
The reactions of 1-benzyl-4-((phenylthio/phenylseleno)methyl)-1H-1,2,3-triazole (L1/L2) and 4-phenyl-1-((phenylthio/phenylseleno)methyl)-1H-1,2,3-triazole (L3/L4), synthesized
using the click reaction, with [(η5-Cp*)RhCl(μ-Cl)]2 and [(η5-Cp*)IrCl(μ-Cl)]2 at room temperature followed by treatment with NH4PF6 result in complexes of the type [[(η5-Cp*)M(L)Cl] (1–8). Their HR-MS
and 1H, 13C{1H}, and 77Se{1H} NMR spectra have been found characteristic. The
single-crystal structures of 2, 3, and 6 have been established by X-ray crystallography. There is
a pseudo-octahedral “piano-stool” disposition of donor
atoms around Rh/Ir. In 1, 2, 5, and 6 N(3) of the triazole skeleton coordinates with
Rh/Ir, whereas in the other four complexes the nitrogen involved is
N(2). These complexes have been explored as catalysts for N-methylmorpholine N-oxide (NMO) based
and Oppenauer-type oxidation of alcohols and transfer hydrogenation
(TH) of carbonyl compounds with 2-propanol. Oppenauer type oxidation
is somewhat slower than that based on NMO. The homogeneous nature
of TH is supported by a poisoning test. The catalytic processes are
more efficient with Rh complexes than the corresponding Ir complexes.
The complexes having N(2) coordinated with the metal have shown better
activity than those in which N(3) is involved in ligation. The reactivity
with respect to ligands is in the order Se > S. In TH the species
formed with loss of Cp* appears to be involved in catalysis with Rh
as well as Ir complexes. Such a loss is noticed in the case of Rh
for the first time. Generally results of DFT calculations are consistent
with the experimental results.
Suzuki-Miyaura C-C cross coupling (SMC), an important synthetic strategy for many organic molecules, has several advantages such as mild reaction conditions, high tolerance toward various functional groups and ease in isolation of the product. Palladium(II) ligated with phosphines (particularly bulky and electron-rich) and N-heterocyclic carbenes (NHCs) has been found to be efficient in the catalysis of SMC. The drawback with many of these catalysts is their air/moisture sensitivity. Since 2000, palladium(II) complexes of organosulphur and related ligands have emerged as viable alternatives to palladium-phosphine/carbene complexes as they have sufficient thermal stability, air and moisture insensitivity. Moreover synthesis of complexes of such ligands is easy. In this perspective Suzuki-Miyaura C-C coupling reactions catalyzed with palladium(II)-complexes of organosulphur ligands have been reviewed. Catalysis of SMC with palladium(II) complexes of organoselenium and tellurium ligands, studied much less in comparison to those of organosulphur ligands, is also included.
Organoselenium ligands are building blocks of several transition metal complexes which catalyze various organic reactions efficiently in solution. In this review the survey of developments pertaining to the designing of such complexes (along with their Se-ligands), and their uses as catalysts for various organic reactions has been presented with critical analysis of present status of the subject. Undoubtedly a new family of catalysts or their precursors has been generated by organoselenium ligands. The catalytic activity and selectivity of their metal complexes can sometimes be fine-tuned efficiently by changing the ligand's framework. They show good thermal and air-stability. This, coupled with ease in their handling and synthesis, may make them not only attractive but good alternatives to several popular catalysts.
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