Ritwika Ray

An iron catalyzed regioselective oxidation of terminal alkenes to aldehydes

Fe(BF(4))(2)·6H(2)O with pyridine-2,6-dicarboxylic acid and PhIO can efficiently catalyze the regioselective oxidation of terminal alkene derivatives to aldehydes under mild and benign reaction conditions.

Uncommon cis configuration of a metal-metal bridging noninnocent Nindigo ligand.

In contrast to several reported coordination compounds of trans-Nindigo ligands [Nindigo = indigo-bis(N-arylimine) = LH2] with one or two six-membered chelate rings involving one indole N and one extracyclic N for metal binding, the new diruthenium complex ion [(acac)2Ru(μ,η(2):η(2)-L)Ru(bpy)2](2+) = 2(2+) exhibits edge-sharing five- and seven-membered chelate rings in the first documented case of asymmetric bridging by a Nindigo ligand in the cis configuration [L(2-) = indigo-bis(N-phenylimine)dianion]. The dication in compound [2](ClO4)2 displays one Ru(α-diimine)3 site and one ruthenium center with three negatively charged chelate ligands. Compound [2](ClO4)2 is obtained from the [Ru(bpy)2](2+)-containing cis precursor [(LH)Ru(bpy)2]ClO4 = [1]ClO4, which exhibits intramolecular H-bonding in the cation. Four accessible oxidation states each were characterized for the 1(n) and 2(n) redox series with respect to metal- or ligand-centered electron transfer, based on X-ray structures, electron paramagnetic resonance, and ultraviolet-visible-near-infrared spectroelectrochemistry in conjunction with density functional theory calculation results. The structural asymmetry in the Ru(III)/Ru(II) system 2(2+) is reflected by the electronic asymmetry (class I mixed-valence situation), leaving the noninnocent Nindigo bridge as the main redox-active site.

Revelation of Varying Bonding Motif of Alloxazine, a Flavin Analogue, in Selected Ruthenium(II/III) Frameworks

The reaction of alloxazine (L) and Ru(II)(acac)2(CH3CN)2 (acac(-) = acetylacetonate) in refluxing methanol leads to the simultaneous formation of Ru(II)(acac)2(L) (1 = bluish-green) and Ru(III)(acac)2(L(-)) (2 = red) encompassing a usual neutral α-iminoketo chelating form of L and an unprecedented monodeprotonated α-iminoenolato chelating form of L(-), respectively. The crystal structure of 2 establishes that N5,O4(-) donors of L(-) result in a nearly planar five-membered chelate with the {Ru(III)(acac)2(+)} metal fragment. The packing diagram of 2 further reveals its hydrogen-bonded dimeric form as well as π-π interactions between the nearly planar tricyclic rings of coordinated alloxazine ligands in nearby molecules. The paramagnetic 2 and one-electron-oxidized 1(+) display ruthenium(III)-based anisotropic axial EPR in CH3CN at 77 K with ⟨g⟩/Δg of 2.136/0.488 and 2.084/0.364, respectively (⟨g⟩ = {1/3(g1(2) + g2(2) + g3(2))}(1/2) and Δg = g1 - g3). The multiple electron-transfer processes of 1 and 2 in CH3CN have been analyzed by DFT-calculated MO compositions and Mulliken spin density distributions at the paramagnetic states, which suggest successive two-electron uptake by the π-system of the heterocyclic ring of L (L → L(•-) → L(2-)) or L(-) (L(-) → L(•2-) → L(3-)) besides metal-based (Ru(II)/Ru(III)) redox process. The origin of the ligand as well as mixed metal-ligand-based multiple electronic transitions of 1(n) (n = +1, 0, -1, -2) and 2(n) (n = 0, -1, -2) in the UV and visible regions, respectively, has been assessed by TD-DFT calculations in each redox state. The pKa values of 1 and 2 incorporating two and one NH protons of 6.5 (N3H, pKa1)/8.16 (N1H, pKa2) and 8.43 (N1H, pKa1), respectively, are estimated by monitoring their spectral changes as a function of pH in CH3CN-H2O (1:1). 1 and 2 in CH3CN also participate in proton-driven internal reorganizations involving the coordinated alloxazine moiety, i.e., transformation of an α-iminoketo chelating form to an α-iminoenolato chelating form and the reverse process without any electron-transfer step: Ru(II)(acac)2(L) (1) → Ru(II)(acac)2(L(-)) (2(-)) and Ru(III)(acac)2(L(-)) (2) → Ru(III)(acac)2(L) (1(+)).

Tunable Electrochemical and Catalytic Features of BIAN- and BIAO-Derived Ruthenium Complexes

This article deals with a class of ruthenium-BIAN-derived complexes, [Ru(II)(tpm)(R-BIAN)Cl]ClO4 (tpm = tris(1-pyrazolyl)methane, R-BIAN = bis(arylimino)acenaphthene, R = 4-OMe ([1a]ClO4), 4-F ([1b]ClO4), 4-Cl ([1c]ClO4), 4-NO2 ([1d]ClO4)) and [Ru(II)(tpm)(OMe-BIAN)H2O](2+) ([3a](ClO4)2). The R-BIAN framework with R = H, however, leads to the selective formation of partially hydrolyzed BIAO ([N-(phenyl)imino]acenapthenone)-derived complex [Ru(II)(tpm)(BIAO)Cl]ClO4 ([2]ClO4). The redox-sensitive bond parameters involving -N═C-C═N- or -N═C-C═O of BIAN or BIAO in the crystals of representative [1a]ClO4, [3a](PF6)2, or [2]ClO4 establish its unreduced form. The chloro derivatives 1a(+)-1d(+) and 2(+) exhibit one oxidation and successive reduction processes in CH3CN within the potential limit of ±2.0 V versus SCE, and the redox potentials follow the order 1a(+) < 1b(+) < 1c(+) < 1d(+) ≈ 2(+). The electronic structural aspects of 1a(n)-1d(n) and 2(n) (n = +2, +1, 0, -1, -2, -3) have been assessed by UV-vis and EPR spectroelectrochemistry, DFT-calculated MO compositions, and Mulliken spin density distributions in paramagnetic intermediate states which reveal metal-based (Ru(II) → Ru(III)) oxidation and primarily BIAN- or BIAO-based successive reduction processes. The aqua complex 3a(2+) undergoes two proton-coupled redox processes at 0.56 and 0.85 V versus SCE in phosphate buffer (pH 7) corresponding to {Ru(II)-H2O}/{Ru(III)-OH} and {Ru(III)-OH}/{Ru(IV)═O}, respectively. The chloro (1a(+)-1d(+)) and aqua (3a(2+)) derivatives are found to be equally active in functioning as efficient precatalysts toward the epoxidation of a wide variety of alkenes in the presence of PhI(OAc)2 as oxidant in CH2Cl2 at 298 K, though the analogous 2(+) remains virtually inactive. The detailed experimental analysis with the representative precatalyst 1a(+) suggests the involvement of the active {Ru(IV)═O} species in the catalytic cycle, and the reaction proceeds through the radical mechanism, as also supported by the DFT calculations.

Efficient Iron-Catalyzed Acetal Formation from Styrene Derivatives

Acetals have immense industrial significance as diesel additives and polymeric materials and as flavoring agent in beverages, cosmetics, and foods. Acetalization is the most useful synthetic technique in any targeted organic synthesis to protect the aldehyde and ketone groups of various multifunctional organic molecules. Acetals constitute a versatile class of organic synthons and intermediates, as they can easily be converted into other useful functional groups. 3] Moreover, acetals are the common functional group in natural products such as ( )xylomollin, anthogorgiene D, allamcin, incargutine B, and so on. The enzyme glycosyltransferase catalyzes the formation of acetals from hemiacetals during the formation of glycosidic bonds in cellulose. Furthermore, the influential role of acetals in biological activities has recently been demonstrated.

Highly Selective Ruthenium-Catalyzed Direct Oxygenation of Amines to Amides

Reports on aerobic oxidation of amines to amides are rare, and those reported suffer from several limitations like poor yield or selectivity and make use of pure oxygen under elevated pressure. Herein, we report a practical and an efficient ruthenium-catalyzed synthetic protocol that enables selective oxidation of a broad range of primary aliphatic, heterocyclic and benzylic amines to their corresponding amides, using readily available reagents and ambient air as the sole oxidant. Secondary amines instead, yield benzamides selectively as the sole product. Mechanistic investigations reveal intermediacy of nitriles, which undergo hydration to afford amide as the final product.

Ruthenium-Catalyzed Aerobic Oxidation of Amines

Amine oxidation is one of the fundamental reactions in organic synthesis as it leads to a variety of value-added products such as oximes, nitriles, imines, and amides among many others. These products comprise the key N-containing building blocks in the modern chemical industry, and such transformations, when achieved in the presence of molecular oxygen without using stoichiometric oxidants, are much preferred as they circumvent the production of unwanted wastes. In parallel, the versatility of ruthenium catalysts in various oxidative transformations is well-documented. Herein, this review focuses on aerobic oxidation of amines specifically by using ruthenium catalysts and highlights the major achievements in this direction and challenges that still need to be addressed.

CCDC 1515770: Experimental Crystal Structure Determination

Related Article: Ritwika Ray, Shubhadeep Chandra, Vishal Yadav, Prasenjit Mondal, Debabrata Maiti, Goutam Kumar Lahiri|2017|Chem.Commun.|53|4006|doi:10.1039/C6CC10200J