We report anew visible-light-mediated carbonylative amidation of aryl, heteroaryl, and alkyl halides.Atandem catalytic cycle of [Ir(ppy) 2 (dtb-bpy)] + generates ap otent iridium photoreductant through as econd catalytic cycle in the presence of DIPEA, whichp roductively engages aryl bromides,i odides,a nd even chlorides as well as primary, secondary,a nd tertiary alkyli odides.T he versatile in situ generated catalyst is compatible with aliphatic and aromatic amines,shows high functional-group tolerance,and enables the late-stage amidation of complex natural products.
Photolysis of 1 in argon-saturated acetonitrile yields 2, whereas in oxygen-saturated acetonitrile small amounts of benzoic acid and benzamide are formed in addition to 2. Similarly, photolysis of 2 in argon-saturated acetonitrile results in 1 and a trace amount of 3, whereas in oxygen-saturated acetonitrile the major product is 1 in addition to the formation of small amounts of benzoic acid and benzamide. Laser flash photolysis of 1 results in an absorption due to triplet vinylnitrene 4 (broad absorption with λ(max) at 360 nm, τ = 1.8 μs, acetonitrile) that is formed with a rate constant of 1.2 × 10(7) s(-1) and decays with a rate constant of 5.6 × 10(5) s(-1). Laser flash photolysis of 2 in argon-saturated acetonitrile likewise results in the formation of triplet vinylnitrene 4 but also ylide 5 (λ(max) at 440 nm, τ = 13 μs). The rate constant for forming 4 in argon-saturated acetonitrile is 1.6 × 10(7) s(-1). In oxygen-saturated acetonitrile, vinylnitrene 4 reacts to form the peroxide radical 6 (λ(max) 360 nm, ~0.7 μs, acetonitrile) at a rate of 2 × 10(9) M(-1) s(-1). Density functional theory calculations were performed to aid in the characterization of vinylnitrene 4 and peroxide 6 and to support the proposed mechanism for the formation of these intermediates.
Photolysis of 3-methyl-2-phenyl-2H-azirine (1a) in argon-saturated acetonitrile does not yield any new products, whereas photolysis in oxygen-saturated acetonitrile yields benzaldehyde (2) by interception of vinylnitrene 5 with oxygen. Similarly, photolysis of 1a in the presence of bromoform allows the trapping of vinylnitrene 5, leading to the formation of 1-bromo-1-phenylpropan-2-one (4). Laser flash photolysis of 1a in argon-saturated acetonitrile (λ = 308 nm) results in a transient absorption with λ(max) at ~440 nm due to the formation of triplet vinylnitrene 5. Likewise, irradiation of 1a in cryogenic argon matrixes through a Pyrex filter results in the formation of ketene imine 11, presumably through vinylnitrene 5. In contrast, photolysis of 2-methyl-3-phenyl-2H-azirine (1b) in acetonitrile yields heterocycles 6 and 7. Laser flash photolysis of 1b in acetonitrile shows a transient absorption with a maximum at 320 nm due to the formation of ylide 8, which has a lifetime on the order of several milliseconds. Similarly, photolysis of 1b in cryogenic argon matrixes results in ylide 8. Density functional theory calculations were performed to support the proposed mechanism for the photoreactivity of 1a and 1b and to aid in the characterization of the intermediates formed upon irradiation.
The general catalytic synthesis of aryl and vinyl thioethers from readily available halides remains a challenge. Herein we report a unified method for the thiolation of aryl and vinyl iodides with dialkyl disulfides using visible light photoredox catalysis. A range of thioether products bearing diverse functional groups can be accessed in high yield and with excellent chemoselectivity. We demonstrate the versatility of this method through the expedient synthesis of a family of thioether-rich natural products. A detailed investigation of the photocatalytic mechanism is presented from both steady-state and time-resolved luminescent quenching as well as transient absorption spectroscopy experiments.
Acceptorless dehydrogenation of ethane
was achieved in the gas
phase via a two-step catalytic cycle involving ternary cationic metal
hydrides, [(phen)M(H)]+, 1, and metal ethides,
[(phen)M(CH2CH3)]+, 2, (where M = Ni, Pd, or Pt, and phen = 1,10-phenanthroline). Species 1 and 2 were generated and their reactivity studied
in a quadrupole ion trap mass spectrometer. It was found that 1 readily reacted with ethane releasing H2 and
forming 2, with the relative reactivity being Pt >
Ni
≫ Pd. Density functional theory (DFT) calculations for this
metathesis reaction agree with the experimental reactivity order.
Species 2 can in turn be converted into 1 and release ethylene when sufficient energy is supplied via collision-induced
dissociation. DFT calculations also provided insight into competing
side reactions (e.g., dehydrogenation of 2 and formation
of protonated phen ligand) that become competitive during this endothermic
step. The catalytic cycle can be repeated in the mass spectrometer
several times. Multiple entry points into the cycle have been identified
and discussed.
Visible light irradiation of 8-aminoquinoline Pd(ii) complexes initiates photoinduced electron transfer with alkyl halides, affording C–H halogenation over C–C bond adducts. A method for inert C(sp3)–H bond halogenation (Br, Cl and I) is reported.
The
ternary Pd complexes [(phen)Pd(H)]+ (1-Pd)
and [(phen)Pd(CH3)]+ (5-Pd)
(where phen = 1,10-phenanthroline) both react with hexane in a linear
ion trap mass spectrometer, forming the C–H activation product
[(phen)Pd(C6H11)]+ (3-Pd) and releasing H2 and CH4, respectively. Density
functional theory (DFT) calculations agree well with the experiments
in predicting low barriers for these reactions proceeding via a metathesis
mechanism. Species 3-Pd undergoes extensive fragmentation,
or “cracking”, of the hydrocarbon chain when sufficient
energy is supplied via collision-induced dissociation (CID), resulting
in the extrusion of a mixture of alkenes, methane, and hydrogen. DFT
calculations show that Pd “chain-walking” from α
(terminal carbon) to β and from β to γ positions
can proceed with barriers sufficiently below those required for chain
“cracking”. The fragmentation reactions can be made
catalytic if 1-Pd and 5-Pd produced by CID
of 3-Pd are allowed to react with hexane again. Ni complexes
largely mirrored the chemistry observed for Pd. Both 1-Ni and 5-Ni reacted with hexane, forming 3-Ni, which fragmented under CID conditions in a fashion similar to 3-Pd. In contrast, only 5-Pt reacted with hexane
to form 3-Pt, which fragmented predominantly via sequential
losses of H2.
Using fatty acids as renewable sources of biofuels requires deoxygenation. While a number of promising catalysts have been developed to achieve this, their operating mechanisms are poorly understood. Here, model molecular systems are studied in the gas phase using mass spectrometry experiments and DFT calculations. The coordinated metal complexes [(phen)M(O2CR)]+ (where phen=1,10‐phenanthroline; M=Ni or Pd; R=CnH2n+1, n≥2) are formed via electrospray ionization. Their collision‐induced dissociation (CID) initiates deoxygenation via loss of CO2 and [C,H2,O2]. The CID spectrum of the stearate complexes (R=C17H35) also shows a series of cations [(phen)M(R’)]+ (where R’ < C17) separated by 14 Da (CH2) corresponding to losses of C2H4‐C16H32 (cracking products). Sequential CID of [(phen)M(R’)]+ ultimately leads to [(phen)M(H)]+ and [(phen)M(CH3)]+, both of which react with volatile carboxylic acids, RCO2H, (acetic, propionic, and butyric) to reform the coordinated carboxylate complexes [(phen)M(O2CR)]+. In contrast, cracking products with longer carbon chains, [(phen)M(R)]+ (R>C2), were unreactive towards these carboxylic acids. DFT calculations are consistent with these results and reveal that the approach of the carboxylic acid to the “free” coordination site is blocked by agostic interactions for R > CH3.
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